CROSS-REFERENCE TO RELATED APPLICATION The present application is a nonprovisional and claims the benefit of 60/811,465 including CD filed Jun. 5, 2006, which is incorporated by reference in its entirety for all purposes.
BACKGROUND OF THE INVENTION Major depressive disorder (MDD) is a serious medical illness affecting about 10 million American adults. In a given year, about 5-7% adults in the developed countries suffer from mood disorders, a cluster of mental disorders best recognized by depression or mania. Unlike normal emotional experiences of sadness, loss, or passing mood states, major depression is persistent and can significantly interfere with an individual's thoughts, behavior, mood, activity, and physical health. Among all medical illnesses, major depression is the leading cause of disability in the U.S. and many other developed countries. The occurrence rate for MDD is two times higher among women than among men (Blehar et al., Medscape Women's Health 2:3 (1997)). Major depression can occur at any age including childhood, the teenage years and adulthood. All ethnic, racial and socioeconomic groups suffer from depression. About three-fourths of those who experience a first episode of depression will have at least one other episode in their lives. Some individuals may have several episodes in the course of a year. If untreated, episodes commonly last anywhere from six months to a year. Left untreated, depression can lead to suicide.
Several different treatment options are available for patients with depression as well as psychiatric counseling. The therapeutic effects of antidepressants are believed to be related to an effect on neurotransmitters, particularly by inhibiting the monoamine transporter proteins of serotonin and norepinephrine. Selective serotonin reuptake inhibitors (SSRIs) specifically prevent the reuptake of serotonin (thereby increasing the level of serotonin in synapses of the brain), whereas earlier monoamine oxidase inhibitors (MAOIs) blocked the destruction of neurotransmitters by enzymes which normally break them down. Tricyclic antidepressants (TCAs) prevent the reuptake of various neurotransmitters, including serotonin, norepinephrine, and dopamine.
At present no specific genetic or biochemical tests are available for the positive diagnosis of depression. Diagnosis and treatment is presently based solely on patient self-reporting and symptom description. The clinical heterogeneity associated with depression has complicated patient reporting as well as the diagnosis and treatment of the disorder. As a result, no clear modality of treatment for all individuals with depression has emerged, and treatment as well as diagnosis varies greatly not only from patient to patient but from physician to physician. Thus, many sufferers of depression are not effectively treated.
SUMMARY OF THE CLAIMED INVENTION The invention provides a method of polymorphic profiling an individual. The method comprises determining a polymorphic profile in at least two but no more than 1000 polymorphic sites, the polymorphic sites including at least two sites shown in Table 1 or in linkage disequilibrium therewith. Optionally, the polymorphic profile is determined in at least two polymorphic sites shown in Table 3. Optionally, the polymorphic profile is determined in at least 2 and no more than 50 different polymorphic sites shown in Table 3. Optionally, the polymorphic profile is determined in at least 5 polymorphic sites shown in Table 1 or 3. Optionally, the polymorphic profile is determined in at least 10 polymorphic sites shown in Table 1 or 3. Optionally, the polymorphic profile is determined in at least two polymorphic sites in or within 10 kb of the at least two genes shown in Table 1. Optionally, the polymorphic profile is determined in at least two polymorphic sites in or within 10 kb of at least two genes shown in Table 2. Optionally, the polymorphic profile is determined in at least two polymorphic sites in at least two genes shown in Table 1 or Table 2. Optionally, the polymorphic profile is determined at polymorphic sites in at least 5 genes shown in Table 1 or Table 2. Optionally, the polymorphic profile is determined in at least two polymorphic sites shown in Table 1 or 3. Optionally, the polymorphic profile is determined in at least five polymorphic sites shown in Table 1 or 3. Optionally, one of the polymorphic sites is in the TTC12 gene or in linkage disequilibrium therewith. Optionally, one of the polymorphic sites is SNP No. 1752273.
The invention further provides a method of determining whether a patient with depression is suitable for treatment with an SSRI or inclusion in a clinical trial for testing an SSRI. The method comprises determining presence of a polymorphic profile in at least one polymorphic site shown in Table 1 or 3 or in linkage disequilibrium therewith; and determining whether to treat the patient with the SSRI or include the patient in a clinical trial based on the polymorphic profile. Optionally, the method further comprises determining the total number of alleles in the polymorphic profile associated with a positive response to SSRIs and the total number of alleles in the polymorphic profile associated with a negative (or lack of) response to SSRIs, whereby a higher number of alleles associated with the positive response than alleles associated with a negative response is an indication of whether a patient with depression is amenable to treatment with SSRIs or should be included in a clinical trial for testing an SSRI. Optionally, the method further comprises determining the total number of alleles in the polymorphic profile associated with a positive response to placebo and the total number of alleles in the polymorphic profile associated with a negative response (or lack of) to placebo, whereby a higher number of alleles associated with the positive response than alleles associated with a negative response is an indication of whether a patient is susceptible to a placebo effect or should be excluded from a clinical trial for testing an SSRI. Optionally, the method determines which polymorphic forms are present in at least 10 polymorphic sites shown in Table 1 or Table 3. Optionally, the method further comprises treating the patient with an SSRI. Optionally, the method further comprises treating the patient with a treatment for depression other than with an SSRI. Optionally, the method further comprises further comprises performing a clinical trial to test an SSRI on a population including the patient. Optionally, the method further comprises performing a clinical trial to test the SSRI on a population not including the patient. Optionally, one of the polymorphic sites is in the gene TTC12 or in linkage disequilibrium therewith. Optionally, the polymorphism is SNP No. 1752273.
The invention further provides a method of expression profiling. The method comprises determining expression levels of at least 2 and no more than 10,000 genes in a subject, wherein at least two of the genes are from Table 1 or 2, the expression levels forming an expression profile. Optionally, the subject has depression. Optionally, the method further comprises determining expression levels of the genes in an individual not having depression to determine genes differentially expressed in depression. Optionally, the method further comprises determining the expression levels of the genes in a positive control subject having depression and amenable to treatment with SSRIs and a negative control subject having depression and not amenable to treatment with SSRIs, and comparing the expression levels of the genes in the subject with expression levels of the genes in the positive control and negative control, wherein similarity of expression profiles in the subject and the positive control is an indication the subject is amenable to treatment with an SSRI, and similarity of the expression profiles in the subject and the negative is an indication that the subject is not amenable to treatment with an SSRI. Optionally, the expression levels of at least five genes shown in Table 1 or 2 are determined. Optionally, the determining step determines the expression level of at least 2 and no more than 100 genes, wherein the at least two genes are shown in Table 1 or 2. Optionally, the determining step determines the expression levels of at least 5 genes shown in Table 1 or 2. Optionally, the determining step determines the expression levels of at least 10 genes shown in Table 1 or 2.
The invention further provides a method of screening a compound activity in modulating depression. The method comprises determining whether a compound binds to, modulates expression of, or modulates the activity of a polypeptide encoded by a gene shown in Table 1 or Table 2. Optionally the determining comprises contacting the compound with the polypeptide and detecting specific binding between the compound and the polypeptide. Optionally, the determining comprises contacting the compound with the polypeptide and detecting a modulation of activity of the polypeptide. Optionally, the determining comprises contacting the gene or other nucleic acid encoding the polypeptide with the compound and detecting a modulation of expression of the polypeptide.
The invention further provides a method of effecting treatment or prophylaxis of depression. The method comprises administering to a subject having or at risk of depression a compound that modulates expression or activity of a gene shown in Table 1 or 2. Optionally, the compound is selected from the group consisting of an antibody that specifically binds to a protein encoded by a gene shown in Table 1 or 2; a zinc finger protein that modulates expression of a gene shown in Table 1 or 2; an siRNA, antisense RNA, RNA complementary to a regulatory sequence, or ribozyme that inhibits expression of a gene shown in Table 1 or 2. Optionally, the gene is shown in Table 1 or 2.
The invention further provides a transgenic nonhuman animal having a genome comprising an exogenous gene shown in Table 1 or 2.
The invention further provides a transgenic nonhuman animal having a genome with a disrupted endogenous gene that is a species variant of a gene shown in Table 1 or 2.
DEFINITIONS A polymorphic site is a locus of genetic variation in a genome. A polymorphic site is occupied by two or more polymorphic forms (also known as variant forms or alleles). A single nucleotide polymorphic site (SNP) is a variation at a single nucleotide.
The term “haplotype block” refers to a region of a chromosome that contains one or more polymorphic sites (e.g., 1-10) that tend to be inherited together (i.e., are in linkage disequilibrium) (see Patil et al., Science, 294:1719-1723 (2001); US 20030186244)). Combinations of polymorphic forms at the polymorphic sites within a block cosegregate in a population more frequently than combinations of polymorphic sites that occur in different haplotype blocks.
The term “haplotype pattern” refers to a combination of polymorphic forms that occupy polymorphic sites, usually SNPs, in a haplotype block on a single DNA strand. For example, the combination of variant forms that occupy all the polymorphisms within a particular haplotype block on a single strand of nucleic acid is collectively referred to as a haplotype pattern of that particular haplotype block. Many haplotype blocks are characterized by four or fewer haplotype patterns in at least 80% of individuals. The identity of a haplotype pattern can often be determined from one or more haplotype determining polymorphic sites (e.g., “tag SNPs”) without analyzing all polymorphic sites constituting the pattern.
The term “linkage disequilibrium” refers to the preferential segregation of a particular polymorphic form at one polymorphic site with another polymorphic form at a different polymorphic site more frequently than expected by chance. Such polymorphic forms, polymorphic sites at which the polymorphic forms occur, and genes including the polymorphic sites are said to be in linkage disequilibrium with each other. Linkage disequilibrium can also refer to a situation in which a phenotypic trait displays preferential segregation with a particular polymorphic form or another phenotypic trait more frequently than expected by chance.
A polymorphic site is proximal to a gene if it occurs within the intergenic region between the transcribed region of the gene and that of an adjacent gene. Usually, proximal implies that the polymorphic site occurs closer to the transcribed region of the particular gene than that of an adjacent gene. Typically, proximal implies that a polymorphic site is within 50 kb, and preferably within 10 kb of the transcribed region. Polymorphic sites not occurring in proximal regions as defined above are said to occur in regions that are distal to the gene.
Specific binding between two entities means a mutual affinity of at least 106 M−1, and usually at least 107 or 10 M−1. The two entities also usually have at least 10-fold greater affinity for each other than the affinity of either entity for an irrelevant control.
A nonhuman homolog of a human gene is the gene in a nonhuman species, such as a mouse, that shows greatest sequence identity at the nucleic acid and encoded protein level, and higher order structure and function of the protein product to that of the human gene or encoded product.
Modulation means a change in the function of a gene product. For example, such change may be related to an increase or decrease in activity or expression, or altered timing of expression or activity.
The terms “isolated” and “purified” refer to a material that is substantially or essentially removed from or concentrated in its natural environment. For example, an isolated nucleic acid is one that is separated from the nucleic acids that normally flank it or from other biological materials (e.g., other nucleic acids, proteins, lipids, cellular components, etc.) in a sample. In another example, a polypeptide is purified if it is substantially removed from or concentrated in its natural environment.
“Statistically significant” means significant at a p value ≦0.05.
The term “comprising” indicates that other elements can be present besides those explicitly stated.
DETAILED DESCRIPTION OF THE INVENTION I. General The invention provides a collection of polymorphic sites associated with variation in outcome from treatment of patients suffering from depression with a selective serotonin reuptake inhibitor (SSRI) or a placebo. Some polymorphic sites are occupied by variant forms associated with a positive response or negative response to SSRI's. That is, at a given site, one of the alleles is associated with a positive response and the other with a negative response or lack of response. Other polymorphic sites are occupied by variant forms associated with a positive or negative (lack of) response to a placebo. Likewise, this means that at one polymorphic site, one allele is associated with a positive response and the other with a negative response or lack of response. In general, the polymorphic sites associated with response to an SSRI are different from the polymorphic sites associated with response to a placebo.
The collection of polymorphic sites and genes has a variety of uses. Depression patients identified with a variant form or predominance of variant forms associated with a positive outcome to treatment with SSRI's are identified as being suitable for treatment with SSRI's and for inclusion in clinical trials intended to test SSRI's. Conversely, depression patients identified with a variant form or a predominance of variant forms associated with a negative (lack of) response to treatment with SSR's are identified as being less suitable or not suitable for treatment with SSRI's or inclusion in clinical trials to test SSRI's. Individuals identified with a variant form or a predominance of variant forms associated with a positive outcome from placebo (i.e., in the absence of treatment) are indicated as being less suitable or unsuitable for treatment with SSRI's and for inclusion in clinical trials. Individuals identified with a variant form or a predominance of variant forms associated with a negative outcome from placebo are indicated as being suitable for treatment with SSRI's and inclusion in clinical trials.
The genes containing, or in linkage disequilibrium, with the polymorphic sites and their encoded proteins can be used to identify compounds that modulate the expression or activity of the encoded proteins. Such compounds are useful for treating depression, optionally in combination with other treatments, particularly SSRIs. The collection of genes is also useful for generating transgenic animal models of depression. These models are useful for screening compounds to determine presence of pharmacological activity useful for treating depression.
II. Measurement of Response to Treatment A depression patient's response to an SRRI or a placebo can be measured in either a quantitative or binary fashion. A quantitative analysis means that each patient is associated with a value indicating the magnitude of the response (i.e., improvement in the condition of the patient), if any. A binary response means that each patient is classified as responding (i.e., improving in condition) or not responding based on whether the patient achieves a predefined threshold response value. Irrespective whether the analysis is quantitative or binary, the response can be evaluated on several different scales of depression including HAM-D, or its subscales: insomnia, anxiety and Core Lilly.
An allele is associated with a positive response to treatment with an SRRI or a placebo if the presence of the allele correlates positively and significantly with the magnitude of the response or rate of response (inverse of time) on any quantitative scale of severity of depression or its component phenotypes in a population of patients so treated. An allele is also associated with a positive response to treatment with an SSRI or placebo if the allele is present significantly more frequently in a population of patients achieving a threshold value of response on any quantitative scale than not a achieving a threshold in a binary analysis. Conversely, an allele is associated with a negative (or lack of) response to treatment with an SSRI or placebo if the presence of the allele correlates negatively and significantly with the magnitude or rate of the response in a population of patients. An allele is also associated with a negative (lack of) response to treatment with an SSRI or a placebo if the allele is present significantly less frequently in a population of patients achieving a threshold than in a population not achieving a threshold value of response on any quantitative scale in a binary analysis. In general, each polymorphic site of the invention can be occupied by two variant alleles, one of which associates with a positive response to treatment with an SSRI or a placebo and the other a negative (lack of) response to treatment with an SSRI or a placebo.
III. Polmorphic Sites and Genes The invention provides a large collection of polymorphic sites associated with response to SSRIs and/or a placebo as shown in Table 1. The first and second columns provide identification numbers for each SNP. The first column is an internal Perlegen number. The second column is the reference number according to dbSNP database established and maintained by NCBI of the National Library of Medicine at the National Institute of Health, Build 34). If a SNP does not have an rs_ID, this means that Perlegen Sciences has not submitted this SNP to dbSNP, but that this is an existing SNP in dbSNP mapped (in the Perlegen alignment process) to the same location as the Perlegen SNP. The third column of the table indicates the chromosome on which the polymorphic site is found. The fourth column provides the accession number for the genomic region containing the SNP. The fifth column provides the location of the SNP in the genomic region identified by the accession number in the fourth column (NCBI, Build 34 of the human genome map). The sixth and seventh columns provide the alternative bases occupying the polymorphic sites. The assignment as ref or alternative does not indicate whether an allele correlates positively or negatively with a placebo or an SRRI response. The eighth column indicates 51 bases of nucleotide sequence centered about a polymorphic site. The ninth column provides the frequency of the reference allele in all tested populations (irrespective of treatment regime). The tenth column lists the genes flanking a polymorphic site with the polymorphic site indicated by square brackets. If the square brackets enclose a gene, the polymorphic site is within the gene. The gene names are those defined by the authorities in the field such as HUGO, or conventionally used in the art to describe the genes. Further information as to whether each polymorphic site associates with an SRRI treatment or placebo response by a variety of scales and measurements on each scale, together with statistical parameters is provided in Tables 5-10 and in the Examples.
Table 2 shows a preferred collection of about 27 genes shown in Table 1, all of which have been identified as “CNS-relevant” based on a search of the published literature and public databases (e.g., some are known to be expressed in the CNS). The first three columns of the Table list the genes, GeneID from the NCBI Gene database, and their functions known to date. The remaining six columns indicate the type of response associated with each gene. A total of 24 different responses were analyzed for a polymorphic site in each gene. Each polymorphic site was analyzed for associations with outcome to treatment with placebo and an SSRI. These analyses are collectively referred to as “by genoytpe” and “by interaction” respectively in Table 2. Both placebo and SSRI responses were analyzed using HAM-D and its three subscales of depression. HAM-D is an overall measure of depression. Insomnia, Core Lilly, and anxiety are measures of included aspects of depression, as discussed in the Examples. Each scale was in turn analyzed by three measures of the response on that scale (time to response, binary, i.e., subject either meets or does not meet an endpoint, or quantitative measure of response). The last six columns in Table 2 are grouped in three pairs. Each pair shows placebo and SSRI responses, and the three pairs show the three different measures of response. If a particular column is occupied by a scale, it signifies that the gene in the same row as the scale contained a polymorphic site for which one allele showed a positive response on the scale and the other allele showed a negative (or lack of) response. Thus, for example, a polymorphic site in the AUTS2 gene contains variant alleles, one of which showed a positive response and the other a negative (or lack of) response to placebo as determined by binary measurement of insomnia and linear (i.e., quantitative) measures of Core Lilly and HAM-D. Likewise, a polymorphic site in the GRM8 gene contains variant alleles, one of which showed a positive response and the other a negative (or lack of) response to placebo as determined by time to respond on the CLilly scale. Likewise a polymorphism in the gene HTR2C contains variant alleles, one of which showed a positive response and the other negative response to SSRI treatment determined by a linear measurement on the CLilly scale.
Table 3 shows polymorphic sites within the genes of Table 2. Some genes contain more than one polymorphic site. The columns of Table 3 correspond to those of Table 1 as discussed above, except that the ninth column provides the identity of a single gene containing the polymorphic site of that row of the table, and the tenth column provides information regarding the analysis or analyses that showed the SNP to be significantly associated. For the three letter designations, the first letter indicates whether the analysis was binary (B), linear (L) or time (T); the second letter indicates whether the analysis was by genotype (G) or by interaction (I); and the third letter indicates which measure was used (e.g., anxiety (A), HAM-D (H), Core Lilly (C), and insomnia (I)). Each of the polymorphic sites shown in Table 3 has one variant form positively associated with either a placebo or an SSRI response, and one variant form negatively associated with either a placebo or an SSRI response.
Table 4 shows additional SNPs in CNS relevant genes that have been associated with a placebo or SSRI effect. The first column indicates the model (e.g., “linearinteract” means association with SSRI effect by a linear measurement). The second column indicates the scale of depression used. Table 4 provides a reference for the SNP used. Further information regarding the SNP can be obtained from Table 1. Columns 5 and 6 provide statistical information regarding the association as further defined below.
Tables 5-10 shows additional SNPs in genes not known to have CNS roles. The first column shows the SNP number. Further information regarding the SNP can be obtained from Table 1. The second and third columns provide statistical information regarding the association as further defined below.
IV. Depression Depression is a mood disorder characterized by persistent feelings of sadness for several weeks or more. There are several subtypes of depression. Major Depressive Disorder (MDD) impairs a person's ability to work, sleep, eat, and function as he or she normally would. It keeps subjects from enjoying activities that were once pleasurable, and causes them to think about themselves and the world in negative ways. MDD is often disabling and may occur several times in a person's lifetime. Dysthymic Disorder (DD) is a milder yet more enduring type of major depression. People with DD may appear to be chronically mildly depressed to the point that it seems to be a part of their personality. When a subject seeks treatment for dysthymia, it is not uncommon that he/she has struggled with this condition for a number of years. Bipolar Disorder also known as manic-depression or manic-depressive disorder is characterized by mood swings that alternates between periods of depression and periods of elation and excitable behavior known as mania. For people who have bipolar disorder, the depressions can be severe and the mania can seriously impair one's normal judgment. When manic, a person is prone towards reckless and inappropriate behavior. Cyclothymic Disorder is a milder yet more enduring type of bipolar disorder. A person's mood alternates between a less severe mania (known as hypomania) and a less severe depression.
Presence of depression can be determined by questionnaire according to the Diagnostic and Statistical Manual of Mental Disorders—Fourth Edition (American Psychiatric Association, 1994) patients. HAM-D is a commonly used scale to assess the severity of depression. The scale was developed for use primarily on patients who have already been diagnosed as suffering from affective disorders. Questions are related to symptoms such as, for example, depressed mood, guilty feelings, suicide, sleep disturbances, anxiety levels and weight loss (Hamilton, J. Neurology Neurosurgery Psychiatry 23:56-62 (1960). Subsets of questions on the HAM-D scale can also be used to calculate subscores for depression, anxiety and insomnia as described in the Examples. Another scale is the Montgomery-Åsberg Depression Rating Scale (MADRS). This scale has been designed to measure the treatment changes of depression. It measures the severity of many symptoms of depression such as, for example, mood and sadness, tension, sleep, appetite, energy, concentration, suicide and restlessness.
Most forms of depression can be treated by psychiatric counseling and a variety of drugs. The most commonly prescribed drugs for depression are SSRIs. Other available classes of drugs are monoamine oxidase inhibitors (MAOIs), tricyclic antidepressants, serotonin-norepinephrine reuptake inhibitors (SNRIs), norepinephrine/noradrenaline reuptake inhibitors (NRIs aka NERIs/NARIs), dopamine reuptake inhibitors (DRIs), opioids, selective serotonin reuptake enhancers (SSREs), and tetracyclic antidepressants. Within each class there are numerous different drugs. Examples of SSRIs include fluoxetine, paroxetine, citalopram, escitalopram and sertraline. Venlafaxine and duolxetine are examples of SNRIs, Fluvoxamine of an SSRI, and Bupropion of a DRI and NRI.
V. Methods of Polymorphic Profiling The invention provides methods of profiling individuals at one or more SNPs of the invention. A polymorphic profile refers to the matrix of variant forms occupying one or more polymorphic sites. The profile can be determined on at least 1, 2, 5, 10, 25, 35, 50, 100, 500, 1000 or all of polymorphic sites shown in any one of Tables 1, 2, 3, 4, 5A-D, 6A-D, 7A-D, 8A-D, 9A-D and 10A-D, all of these tables, or any combinations thereof and optionally other polymorphisms in linkage disequilibrium with them. The profile can include polymorphic sites from CNS relevant genes (Tables 2-4) or other genes (Tables 5A-D, 6A-D, 7A-D, 8A-D, 9A-D and 10A-D) or a combination thereof. The polymorphic profile is preferably determined in at least 1, 2, 5, 10, 25 or all of the polymorphic sites shown in any of Tables 3, 4, 5A-D, 6A-D, 7A-D, 8A-D, 9A-D and 10A-D, all of these tables or any combination thereof. For polymorphic sites in linkage disequilibrium with a polymorphic site shown in Table 1 or 3, polymorphic sites occurring in the same gene as shown in Table 1 or 3 or proximal thereto are preferred. The polymorphic profile preferably includes polymorphic sites from at least 2, 5, 10, 15, 25 or all of the genes shown in Table 1, 2 and/or 3. The polymorphic profile can alternatively or additionally including polymorphic sites from at least 2, 5, 10, 15, 25 or all the genes containing a polymorphic site shown in any of Tables 4, 5A-D, 6A-D, 7A-D, 8A-D, 9A-D, or 10A-D. The polymorphic sites of the invention can be analyzed in combination with other polymorphic sites. However, the total number of polymorphic sites analyzed is usually less than 10,000, 1000, 100, 50 or 25.
The number of alleles associated positively or negatively with a given response present in a particular individual can be combined additively or as ratio to provide an overall score for the individual's genetic propensity to the response (see US 2005-0196770 A1). For example, alleles associated with a positive response to an SSRI can be arbitrarily each scored as +1 and alleles associated with a negative response as −1 (or vice versa). For example, if an individual is typed at 30 polymorphic sites of the invention and is homozygous for alleles associated with a positive response to an SSRI at all of them, he or she could be assigned a score of 100% genetic amenability to treatment with an SSRI. The reverse applies if the individual is homozygous for all alleles associated with a negative (or lack of) response to an SSRI. More typically, an individual is homozygous for positively associated alleles at some loci, homozygous for negatively associated alleles at some loci, and heterozygous for positively and negatively associated alleles at other loci. Such an individual's genetic amenability to treatment with an SSRI can be scored by assigning all positively associated alleles a score of +1, and all negatively associated alleles a score of −1 (or vice versa) and combining the scores. For example, if an individual has 40 positively associated alleles and 20 negatively associated alleles, the individual can be scored as having a 67% genetic amenability to treatment with an SSRI. Alternatively, homozygous positively associated alleles can be assigned a score of +1, heterozygous alleles a score of zero and homozygous negatively associated alleles a score of −1. The relative numbers of resistance alleles and susceptibility alleles can also be expressed as a percentage. Thus, an individual who is homozygous for positively associated alleles at 20 polymorphic sites, homozygous for negatively associated alleles at 40 polymorphic sites, and heterozygous at 10 sites is assigned a genetic amenability of 33% for treatment with an SSRI. As a further alternative, homozygosity for positively associated alleles can be scored as +2, heterozygosity, as +1 and homozygosity for negatively associated alleles as 0.
Similar calculations can be performed to assess the individual's genetic susceptibility to a placebo response. In general the polymorphic sites associating with a placebo response are different from those associating with an SSRI response, so any given polymorphic site is used in only one of the two calculations.
The nature of the polymorphic profile of an individual and the scores calculated from it are useful in determining how to treat a patient and/or whether to include the patient in a clinical trial to test a new SSRI. If a patient has a genetic amenability to treatment with an SSRI, the test indicates that treatment of the patient with an SSRI should be begun or continued. Alternatively, if the treatment has proved or proves to be unsuccessful, such an outcome signals that a different SSRI should be tried. The test also signifies that the patient is suitable for inclusion in a clinical trial to test a new SSRI. Alternatively, if the patient has a low genetic amenability to treatment with an SSRI, the test indicates that treatment with an SSRI should not be initiated or should be discontinued. The test also provides an indication that the patient should preferably not be included in a clinical trial to test an SSRI.
If the analysis indicates a patient has a high genetic amenability to respond positively to a placebo, the test provides an indication that the individual should not be treated with an SSRI because the patient has a propensity to recover without treatment. However, the test does not distinguish between whether the patient recovers without treatment due to the psychological placebo effect or due to the subtype of depression affecting the patient. Accordingly, the patient can be prescribed a placebo. The test also provides an indication that the patient should be excluded from clinical trials to test an SSRI. If the analysis indicates a patient has a low genetic amenability to a placebo effect, the test provides an indication that some treatment is desirable but does not distinguish whether an SSRI or other treatment is preferred. However, such can be indicated by analysis of polymorphisms associated with the SSRI response. Similarly, a low genetic amenability to a placebo effect provides an indication that the patient is suitable for inclusion in a clinical trial to treat depression but does not indicate whether the patient is amenable to treatment with SSRIs or other treatment. Again, this information can be obtained from analysis of polymorphic sites associated with the SSRI response.
Polymorphic profiling is useful for stratifying individuals in clinical trials of compounds being tested for capacity to treat depression, particularly of SSRIs. Such trials are performed on treated or control populations having similar or identical polymorphic profiles (see WO0033161). Use of genetically matched populations (i.e., statistically significant similarity of polymorphic profile at a defined set of polymorphic sites of the invention relative to similarity of polymorphic profile at these sites in the general population) eliminates or reduces variation in treatment outcome due to genetic factors, leading to a more accurate assessment of the efficacy of a potential drug. This also provides for maximum treatment difference when response to SSRI treatment is assessed against response to placebo treatment in a clinical trial.
Polymorphic profiles can also be used after the completion of a clinical trial to elucidated differences in response to a given treatment. For example, the set of polymorphisms can be used to stratify the enrolled patients into disease sub-types or classes. It is also possible to use the polymorphisms to identify subsets of patients with similar polymorphic profiles who have unusual (high or low) response to treatment or who do not respond at all (non-responders). In this way, information about the underlying genetic factors influencing response to treatment can be used in many aspects of the development of treatment (these range from the identification of new targets, through the design of new trials to product labeling and patient targeting). Additionally, the polymorphisms can be used to identify the genetic factors involved in adverse response to treatment (adverse events). For example, patients who show adverse response may have more similar polymorphic profiles than would be expected by chance. This allows the early identification and modification or protocol or exclusion of such individuals from treatment. It also provides information that can be used to understand the biological causes of adverse events and to modify the treatment to avoid such outcomes.
Polymorphic profiles can also be used for other purposes, including paternity testing and forensic analysis, such as described by U.S. Pat. No. 6,525,185. In forensic analysis, the polymorphic profile from a sample at the scene of a crime is compared with that of a suspect. A match between the two is evidence that the suspect in fact committed the crime, whereas lack of a match excludes the suspect.
Polymorphic profiles can be used in further association studies of traits related to depression. Such traits include presence of depression and its subtypes, related diseases, amenability to treatment of depression with agents other than SSRIs or with combinations of agents, amenability to recovery without treatment or placebo. Polymorphic forms can also be further characterized for their effect on the activity of a gene or its expression levels. Polymorphic forms occurring within a protein coding sequence are likely to effect activity of the encoded protein particularly if the change between forms is nonsynonymous. Polymorphic forms occurring between genes are more likely to affect expression levels. Polymorphic forms occurring in introns can affect expression levels or splice variation.
Although polymorphic profiling can be done at the level of individual polymorphic sites as described above, a more sophisticated analysis can be performed by analyzing haplotype blocks containing SNPs of the invention and/or others in linkage disequilibrium with them (see, e.g., US 20040220750). Each haplotype block can be characterized by two or more haplotype patterns (i.e., combinations of polymeric forms). In some instances, a haplotype pattern can be determined by detecting a single haplotype-determining polymorphic form within a haplotype block. In other instances, multiple polymorphic forms are determined within the block (see Patil et al., Science 294, 1719-23 (2001)). The haplotype pattern at each of the haplotype blocks containing SNPs of the invention in an individual is a factor in determining response to an SRRI or a placebo, and can be characterized as associating positively or negatively with an SSRI or placebo response as can individual polymorphic forms. The number of haplotype blocks occupied by haplotype patterns associated with a positive response and the number associated with a negative response in a particular individual can be combined additively as for individual polymorphic forms to arrive at a percentage representing genetic propensity to positive or negative response. The measure is more accurate than simply combining individual polymorphic forms because it gives the same weight to haplotype blocks containing multiple polymorphic sites as haplotype blocks within a single polymorphic site. The multiple polymorphic forms within the same block are associated with the same propensity to positive or negative response, and should not be given the same weight as multiple polymorphic forms in different haplotype blocks, which indicate independent propensity for positive or negative response.
The methods of the invention detect haplotype patterns in at least 1, 2, 5, 10, 25, 100, 500, 1000 or all of the haplotype blocks of the invention. Preferably, the haplotype patterns include at least 1, 2, 5, 10 or 25 or all of the genes shown in Table 1, 2 or 3. Alternatively or additional, the haplotype patterns can include at least 1, 2, 5, 10 or 25 or all of the genes including a polymorphic site shown in any of Tables 4, 5A-D, 6, A-D, 7A-D, 8A-D, 9A-D, 10A-D. The haplotype patterns can be detected in combination with haplotype patterns at haplotype blocks other than those of the invention. However, the number of haplotype blocks is typically fewer than 10,000, 1000 and often fewer than 100 or 50.
Polymorphic forms can be detected at polymorphic sites by a variety of methods. The design and use of allele-specific probes for analyzing polymorphisms is described by e.g., Saiki et al., Nature 324, 163-166 (1986); EP 235,726; WO 89/11548. Allele-specific probes can be designed that hybridize to a segment of target DNA from one individual but that do not hybridize to the corresponding segment from another individual due to the presence of different polymorphic forms in the respective segments from the two individuals.
The polymorphisms can also be identified by hybridization to nucleic acid arrays, some example of which are described by WO 95/11995. Polymorphic forms can also be detected using allele-specific primers, which hybridize to a site on target DNA overlapping a polymorphism and only primes amplification of an allelic form to which the primer exhibits perfect complementarily. See Gibbs, Nucleic Acid Res. 17, 2427-2448 (1989). Polymorphic forms can also be detected by direct sequences, denaturing gradient gel electrophoresis (Erlich, ed., PCR Technology, Principles and Applications for DNA Amplification, (W.H. Freeman and Co, New York, 1992, Chapter 7), and single stranded polymorphisms analysis (Orita et al., Proc. Nat. Acad. Sci. 86, 2766-2770 (1989)). Polymorphic forms can also be detected by single-base extension methods as described by e.g., U.S. Pat. No. 5,846,710, U.S. Pat. No. 6,004,744, U.S. Pat. No. 5,888,819 and U.S. Pat. No. 5,856,092. The methods hybridize a primer that is complementary to a target sequence such that the 3′ end of the primer is immediately adjacent to but does not span a site of potential variation in the target sequence. That is, the primer comprises a subsequence from the complement of a target polynucleotide terminating at the base that is immediately adjacent and 5′ to the polymorphic site. The hybridization is performed in the presence of one or more labeled nucleotides complementary to base(s) that may occupy the site of potential variation. Some polymorphic forms resulting in a corresponding change in encoded proteins can also be detected at the protein level by immunoassay using antibodies known to be specific for particular variants, or by direct peptide sequencing.
VI. Expression Monitoring The invention also provides methods of expression profiling by determining levels of expression of one or more genes shown in Table 1. The methods preferably determine expression levels of at least 2, 5, 10, 15, 20, 25, 100, 200, 500 or all of the genes shown in Table 1, 2 or 3. Alternatively or additionally, the methods determine expression levels in at least 2, 5, 10, 15, 20, 25, 100, 200, 500 or all of the genes containing a polymorphism shown in any of Tables 4, 5A-D, 6A-D, 7A-D, 8A-D, 9A-D, or 10A-D. Preferably, the expression levels are determined of at least 2, 5, 10, 15, 20, 25 or all of the genes shown in Table 2 or 3. Alternatively or additionally, the expression levels are determined in at least 2, 5, 10, 15, 20, of all of the genes shown in any of Tables 4, 5A-D, 6A-D, 7A-D, 8A-D, 9A-D, or 10A-D. Optionally, expression levels of other genes other than those associated with response to an SSRI or placebo as described in this application are also determined. However, the expression profile is preferably not determined at more than 1000, 5000, or 10,000 genes.
The expression levels of one or more genes in a discrete sample (e.g., from a particular individual or cell line) are referred to as an expression profile. Typically, the expression profile is compared with an expression profile of the same genes in a control sample to determine genes differentially expressed between the two samples. If the test sample is a depression patient, the control can be a subject not having depression. Alternatively, if the test subject is a depression patient being treated with an SSRI, the control can be a depression patient being treated with a placebo, another class of drug, psychotherapy or receiving no treatment. In other methods, the amenability of a test subject to treatment with an SSRI is unknown and the object is to determine the same. In such methods, the expression profile of the test subject is compared with the expression profile of positive and negative control subjects. The positive control subject is an individual known to be amenable to treatment with SSRI. Such an individual at minimum shows a significant benefit from treatment with at least one SSRI and preferably scores in the top ten percentile of depressed individuals in responding to the SSRI. Such an individual can also be recognized by a predominance of alleles positively associated with a response to an SSRI as discussed above. The negative control subject is an individual known to have an insignificant response to at least one SSRI (e.g., scorring in the bottom ten percentile of depressed individuals in responding to the SSRI), and can also be recognized by a predominance of alleles negatively associated with a response to an SSRI, as discussed above. The controls can be contemporaneous or historical. Individual expression levels in both the test and control samples can be normalized before comparison, e.g., by reference to the levels of a housekeeping gene to avoid differences unrelated to the disease.
If the expression profile of the test subject is more similar to that of the positive control than the negative control, the analysis provides an indication that the test subject is amenable to treatment with an SSRI. Conversely if the expression profile of the test subject is more similar to that of the negative control than the positive control, the analysis provides an indication that the test subject is not amenable to treatment with an SSRI. For example, if an expression profile is determined for ten genes of the invention, and the expression levels in the test subject are more similar to the positive control than the negative control for nine of the genes, one can conclude that the test individual is amenable to treatment with an SSRI. The analysis can be performed at a more sophisticated level by weighting expression level according to where they lie between negative and positive controls. For example, if there is a large difference between negative and positive controls, and an expression level of a particular gene in a test individual lies close to the positive control that expression level is accorded greater weight than an expression level in a gene in which there is a smaller difference in expression levels between negative and positive controls, and the expression level of the test individual lies only slightly above the midpoint of the negative and positive control expression levels.
VII. Compounds to Modulate Depression or Response to Treatment Thereof A variety of compounds can be screened for capacity to modulate expression or activity of genes associated with response to treatment of depression with an SSRI or placebo, i.e., the genes shown in Tables 1, 2 and/or 3 or genes containing a polymorphic site shown in any of tables 4, 5A-D, 6A-D, 7A-D, 8A-D, 9A-D, and 10A-D. Compounds can be obtained from natural sources, such as, e.g., marine microorganisms, algae, plants, and fungi. Alternatively, compounds can be from combinatorial libraries of agents, including peptides or small molecules, or from existing repertories of chemical compounds synthesized in industry, e.g., by the chemical, pharmaceutical, environmental, agricultural, marine, cosmeceutical, drug, and biotechnological industries. Compounds can include, e.g., pharmaceuticals, therapeutics, environmental, agricultural, or industrial agents, pollutants, cosmeceuticals, drugs, organic compounds, lipids, glucocorticoids, antibiotics, peptides, proteins, sugars, carbohydrates, and chimeric molecules.
Combinatorial libraries can be produced for many types of compounds that can be synthesized in a step-by-step fashion. Such compounds include polypeptides, proteins, nucleic acids, beta-turn mimetics, polysaccharides, phospholipids, hormones, prostaglandins, steroids, aromatic compounds, heterocyclic compounds, benzodiazepines, oligomeric N-substituted glycines and oligocarbamates. Large combinatorial libraries of compounds can be constructed by the encoded synthetic libraries (ESL) method described in WO 95/12608, WO 93/06121, WO 94/08051, WO 95/35503 and WO 95/30642. Peptide libraries can also be generated by phage display methods. See, e.g., WO91/19818. Compounds to be screened can also be obtained from governmental or private sources, including, e.g., the National Cancer Institute's (NCI) Natural Product Repository, Bethesda, Md., the NCI Open Synthetic Compound Collection, Bethesda, Md., NCI's Developmental Therapeutics Program, or the like. For genes encoding transporters, the compounds include substrates of the transporters, and analogs of the same.
Many compounds currently in use for treating depression can be screened for capacity to modulate the above proteins. The compounds include antibodies, both intact and binding fragments thereof, such as Fabs, Fvs, which specifically bind to a protein encoded by a gene of the invention. Usually the antibody is a monoclonal antibody although polyclonal antibodies can also be expressed recombinantly (see, e.g., U.S. Pat. No. 6,555,310). Examples of antibodies that can be expressed include mouse antibodies, chimeric antibodies, humanized antibodies, veneered antibodies and human antibodies. Chimeric antibodies are antibodies whose light and heavy chain genes have been constructed, typically by genetic engineering, from immunoglobulin gene segments belonging to different species (see, e.g., Boyce et al., Annals of Oncology 14:520-535 (2003)). For example, the variable (V) segments of the genes from a mouse monoclonal antibody may be joined to human constant (C) segments. A typical chimeric antibody is thus a hybrid protein consisting of the V or antigen-binding domain from a mouse antibody and the C or effector domain from a human antibody. Humanized antibodies have variable region framework residues substantially from a human antibody (termed an acceptor antibody) and complementarity determining regions substantially from a mouse-antibody, (referred to as the donor immunoglobulin). See Queen et al., Proc. Natl. Acad. Sci. USA 86:10029-10033 (1989) and WO 90/07861, U.S. Pat. No. 5,693,762, U.S. Pat. No. 5,693,761, U.S. Pat. No. 5,585,089, U.S. Pat. No. 5,530,101 and Winter, U.S. Pat. No. 5,225,539. The constant region(s), if present, are also substantially or entirely from a human immunoglobulin. Antibodies can be obtained by conventional hybridoma approaches, phage display (see, e.g., Dower et al., WO 91/17271 and McCafferty et al., WO 92/01047), use of transgenic mice with human immune systems (Lonberg et al., WO93/12227 (1993)), among other sources. Nucleic acids encoding immunoglobulin chains can be obtained from hybridomas or cell lines producing antibodies, or based on immunoglobulin nucleic acid or amino acid sequences in the published literature.
The compounds also include several categories of molecules known to regulate gene expression, such as zinc finger proteins, ribozymes, siRNAs and antisense RNAs. Zinc finger proteins can be engineered or selected to bind to any desired target site within a gene of the invention. An exemplary motif characterizing one class of these proteins (C2H2 class) is -Cys-(X)2-4-Cys-(X)12-His-(X)3-5-His (where X is any amino acid). A single finger domain is about 30 amino acids in length, and several structural studies have demonstrated that it contains an alpha helix containing the two invariant histidine residues and two invariant cysteine residues in a beta turn co-ordinated through zinc. In some methods, the target site is within a promoter or enhancer. In other methods, the target site is within the structural gene. In some methods, the zinc finger protein is linked to a transcriptional repressor, such as the KRAB repression domain from the human KOX-1 protein (Thiesen et al., New Biologist 2, 363-374 (1990); Margolin et al., Proc. Natl. Acad. Sci. USA 91, 4509-4513 (1994); Pengue et al., Nucl. Acids Res. 22:2908-2914 (1994); Witzgall et al., Proc. Natl. Acad. Sci. USA 91, 4514-4518 (1994)). In some methods, the zinc finger protein is linked to a transcriptional activator, such as VIP16. Methods for selecting target sites suitable for targeting by zinc finger proteins, and methods for design zinc finger proteins to bind to selected target sites are described in WO 00/00388. Methods for selecting zinc finger proteins to bind to a target using phage display are described by EP.95908614.1. The target site used for design of a zinc finger protein is typically of the order of 9-19 nucleotides.
Ribozymes are RNA molecules that act as enzymes and can be engineered to cleave other RNA molecules at specific sites. The ribozyme itself is not consumed in this process, and can act catalytically to cleave multiple copies of mRNA target molecules. General rules for the design of ribozymes that cleave target RNA in trans are described in Haseloff & Gerlach, (1988) Nature 334:585-591 and Hollenbeck, (1987) Nature 328:596-603 and U.S. Pat. No. 5,496,698. Ribozymes typically include two flanking segments that show complementarity to and bind to two sites on a transcript (target subsites) of one of the genes of the invention and a catalytic region between the flanking segments. The flanking segments are typically 5-9 nucleotides long and optimally 6 to 8 nucleotides long. The catalytic region of the ribozyme is generally about 22 nucleotides in length. The mRNA target contains a consensus cleavage site between the target subsites having the general formula NUN, and preferably GUC. (Kashani-Sabet and Scanlon, (1995) Cancer Gene Therapy 2:213-223; Perriman, et al., (1992) Gene (Amst.) 113:157-163; Ruffner, et al., (1990) Biochemistry 29: 10695-10702); Birikh, et al., (1997) Eur. J. Biochem. 245:1-16; and perrealt, et al., (1991) Biochemistry 30:4020-4025). The specificity of a ribozyme can be controlled by selection of the target subsites and thus the flanking segments of the ribozyme that are complementary to such subsites. Ribozymes can be delivered either as RNA molecules, or in the form of DNA encoding the ribozyme as a component of a replicable vector, or in nonreplicable form as described below.
Endogenous expression of a target gene can also be reduced by delivering nucleic acids having sequences complementary to the regulatory region of the target gene (i.e., the target gene promoter and/or enhancers) to form triple helical structures which prevent transcription of the target gene in target cells in the body. See generally, Helene, (1991), Anticancer Drug Des., 6(6):569-584; Helene, et al., (1992), Ann. N.Y. Acad. Sci., 60:27-36; and Maher, (1992), Bioassays 14(12):807-815.
Antisense polynucleotides can cause suppression by binding to, and interfering with the translation of sense mRNA, interfering with transcription, interfering with processing or localization of RNA precursors, repressing transcription of mRNA or acting through some other mechanism (see, e.g., Sallenger et al. Nature 418, 252 (2002). The particular mechanism by which the antisense molecule reduces expression is not critical. Typically antisense polynucleotides comprise a single-stranded antisense sequence of at least 7 to 10 to typically 20 or more nucleotides that specifically hybridize to a sequence from mRNA of a gene of the invention. Some antisense polynucleotides are from about 10 to about 50 nucleotides in length or from about 14 to about 35 nucleotides in length. Some antisense polynucleotides are polynucleotides of less than about 100 nucleotides or less than about 200 nucleotides. In general, the antisense polynucleotide should be long enough to form a stable duplex but short enough, depending on the mode of delivery, to administer in vivo, if desired. The minimum length of a polynucleotide required for specific hybridization to a target sequence depends on several factors, such as G/C content, positioning of mismatched bases (if any), degree of uniqueness of the sequence as compared to the population of target polynucleotides, and chemical nature of the polynucleotide (e.g., methylphosphonate backbone, peptide nucleic acid, phosphorothioate), among other factors.
siRNAs are relatively short, at least partly double stranded, RNA molecules that serve to inhibit expression of a complementary mRNA transcript. Although an understanding of mechanism is not required for practice of the invention, it is believed that siRNAs act by inducing degradation of a complementary mRNA transcript. Principles for design and use of siRNAs generally are described by WO 99/32619, Elbashir, EMB J. 20, 6877-6888 (2001) and Nykanen et al., Cell 107, 309-321 (2001); WO 01/29058. siRNAs are formed from two strands of at least partly complementary RNA, each strand preferably of 10-30, 15-25, or 17-23 or 19-21 nucleotides long. The strands can be perfectly complementary to each other throughout their length or can have single stranded 3′-overhangs at one or both ends of an otherwise double stranded molecule. Single stranded overhangs, if present, are usually of 1-6 bases with 1 or 2 bases being preferred. The antisense strand of an siRNA is selected to be substantially complementary (e.g., at least 80, 90, 95% and preferably 100%) complementary to a segment of a transcript from a gene of the invention. Any mismatched based preferably occur at or near the ends of the strands of the siRNA. Mismatched bases at the ends can be deoxyribonucleotides. The sense strand of an siRNA shows an analogous relationship with the complement of the segment of the gene transcript of interest. siRNAs having two strands, each having 19 bases of perfect complementarity, and having two unmatched bases at the 3′ end of the sense strand and one at the 3′ end of the antisense strand are particularly suitable.
If an siRNA is to be administered as such, as distinct from in the form of DNA encoding the siRNA, then the strands of an siRNA can contain one or more nucleotide analogs. The nucleotide analogs are located at positions at which inhibitor activity is not substantially affected, e.g., in a region at the 5′-end and/or the 3′-end, particularly single stranded overhang regions. Preferred nucleotide analogues are sugar- or backbone-modified ribonucleotides. Nucleobase-modified ribonucleotides, i.e. ribonucleotides, containing a non-naturally occurring nucleobase instead of a naturally occurring nucleobase such as uridines or cytidines modified at the 5-position, e.g. 5-(2-amino)propyl uridine, 5-bromo uridine; adenosines and guanosines modified at the 8 position, e.g. 8-bromo guanosine; deaza nucleotides, e.g. 7-deaza-adenosine; O- and N-alkylated nucleotides, e.g. N6-methyl adenosine are also suitable. In preferred sugar-modified ribonucleotides, the 2′ OH-group is replaced by a group selected from H, OR, R, halo, SH, SR, NH2, NHR, NR2 or CN, wherein R is C1-C6 alkyl, alkenyl or alkynyl and halo is F, CI, Br or I. In preferred backbone-modified ribonucleotides the phosphoester group connecting to adjacent ribonucleotides is replaced by a modified group, e.g. of phosphothioate group. A further preferred modification is to introduce a phosphate group on the 5′ hydroxide residue of an siRNA. Such a group can be introduced by treatment of an siRNA with ATP and T4 kinase. The phosphodiester linkages of natural RNA can also be modified to include at least one of a nitrogen or sulfur heteroatom. Modifications in RNA structure can be tailored to allow specific genetic inhibition while avoiding a general panic response in some organisms which is generated by dsRNA. Likewise, bases can be modified to block the activity of adenosine deaminase.
VIII. Assays to Detect Modulation Compounds are tested for their capacity to modulate expression or activity of one of the genes of the invention (i.e., the genes shown in Tables 1, 2 and/or 3). Expression assays are usually performed in cell culture, but can also be performed in animal models or in an in vitro transcription/translation system. The cell culture can be of primary cells, particularly those known or suspected to have a role in depression, such as cells of the CNS transfected with a gene of the invention. In the latter case, the coding portion of the gene is typically transfected with its naturally associated regulatory sequences, so as to permit expression of the gene in the transfected cell. However, the coding portion of the gene can also be operably linked to regulatory sequences from other (i.e., heterologous) genes. Optionally, the protein encoded by the gene is expressed fused to a tag or marker to facilitate its detection. The compound to be screened is introduced into the cell. The compound can be introduced directly (e.g., as an RNA or protein) or in the form of a DNA molecule that can be expressed. Expression of the gene can be detected either at the mRNA or protein level. Expression at the mRNA level can be detected by e.g., a hybridization assay, and at the protein level by e.g., an immunoassay. Detection of the protein level is facilitated by the presence of a tag. Similar screens can be performed in an animal, either natural or transgenic, or in vitro. Expression levels in the presence of a test compound are compared with those in a control assay in the absence of test compound, an increase or decrease in expression indicating that the compound modulates activity of the gene.
Assays to detect modulation of a protein encoded by a gene of the invention can also be performed. In some instances, a preliminary assay is performed to detect specific binding between a compound and a protein encoded by a gene of the invention. A binding assay can be performed between the compound and a purified protein, of if the protein is expressed extracellularly, between the compound and the protein expressed from a cell. Optionally, either the compound or protein can be immobilized before or during the assay. Such an assay reduces the pool of candidate compounds for an activity assay. The nature of the activity assay depends on the activity of the gene.
Transporters can be assayed by transfecting a cell, such as an oocyte, with DNA encoding the transporter, such that the transporter is expressed in the outer membrane of the cell. The cell is then contacted with a known substrate of the transporter, optionally labeled. Uptake of the substrate can be detected by measuring intracellular label, or ionic or pH gradients across the membrane. Compounds are screened for capacity to inhibit or stimulate transport relative to a control assay lacking the substrate being tested (see, e.g., WO0120331, US2005170394, US2005170390).
Compounds that modulate expression or activity of the genes of the invention can then be tested in animal models of depression (see Willner, Trends Pharmacol Sci. 12, 131-6 (1991)) for modulation of depression or response to treatment thereof. The animal models can be transgenic (as described below) or nontransgenic. Compounds are tested in comparison with otherwise similar control assays except for the absence of the compound being tested. An SRRI can be administered together with a compound under test to assess combinative or synergistic effects. A change in extent of depression of the animal relative to the control indicates a compound modulates depression or response to treatment thereof.
Compounds that modulate expression or activity of the genes of the invention can also be screened in similar fashion in animal models of other neuropsychiatric diseases
IX. Transgenic Animals The invention provides transgenic animals having a genome comprising a transgene comprising one of the genes of the invention (i.e., the genes shown in Tables 1, 2, or 3 or any of the genes containing a polymorphic site shown in Table 4, 5A-D, 6A-D, 7A-D, 8A-D, 9A-D, or 10A-D), or corresponding cDNA or mini-gene nucleic acid. The coding sequence of the gene is in operable linkage with regulatory element(s) required for its expression. Such regulatory elements can include a promoter, enhancer, one or more introns, ribosome binding site, signal sequence, polyadenylation sequence, 5′ or 3′ UTR and 5′ or 3′ flanking sequences. The regulatory sequence can be from the gene being expressed or can be heterologous. If heterologous, the regulatory sequences are usually obtained from a gene known to be expressed in the intended tissue in which the gene of the invention is to be expressed (e.g., the skin).
The invention also provides transgenic animals in which a nonhuman homolog (i.e., species variant) of one of the human genes of the invention is disrupted so as to reduce or eliminate its expression relative to a nontransgenic animal of the same species. Disruption can be achieved either by genetic modification of the nonhuman homolog or by functional disruption by introducing an inhibitor of expression of the gene into the nonhuman animal.
Some transgenic animals have a plurality of transgenes respectively comprising a plurality of genes of the invention. Some transgenic animals have a plurality of disrupted nonhuman homologs of genes of the invention. Some transgenic animals combine both the presence of transgenes expressing one or more genes of the invention and one or more disruptions of nonhuman homologs of other genes of the invention.
Transgenic animals of the invention are preferably rodents, such as mice or rats, or insects, such as Drosophila. Other transgenic animals such as primates, ovines, porcines, caprines and bovines can also be used. The transgene in such animals is integrated into the genome of the animal. The transgene can be integrated in single or multiple copies. Multiple copies are generally preferred for higher expression levels. In a typical transgenic animal all germline and somatic cells include the transgene in the genome with the possible exception of a few cells that have lost the transgene as a result of spontaneous mutation or rearrangement.
For some animals, such as mice and rabbits, fertilization is performed in vivo and fertilized ova are surgically removed. In other animals, particularly bovines, it is preferable to remove ova and fertilize the ova in vitro. See DeBoer et al., WO 91/08216. Methods for culturing fertilized oocytes to the pre-implantation stage are described by Gordon et al., Methods Enzymol. 101, 414 (1984); Hogan et al., Manipulation of the Mouse Embryo: A Laboratory Manual, C.S.H.L. N.Y. (1986) (mouse embryo); Hammer et al., Nature 315, 680 (1985) (rabbit and porcine embryos); Gandolfi et al. J. Reprod. Fert. 81, 23-28 (1987); Rexroad et al., J. Anim. Sci. 66, 947-953 (1988) (ovine embryos) and Eyestone et al. J. Reprod. Fert. 85, 715-720 (1989); Camous et al., J. Reprod. Fert. 72, 779-785 (1984); and Heyman et al. Theriogenology 27, 5968 (1987) (bovine embryos). Sometimes pre-implantation embryos are stored frozen for a period pending implantation. Pre-implantation embryos are transferred to the oviduct of a pseudopregnant female resulting in the birth of a transgenic or chimeric animal depending upon the stage of development when the transgene is integrated. Chimeric mammals can be bred to form true germline transgenic animals.
Alternatively, transgenes can be introduced into embryonic stem cells (ES). These cells are obtained from preimplantation embryos cultured in vitro. Bradley et al., Nature 309, 255-258 (1984). Transgenes can be introduced into such cells by electroporation or microinjection. ES cells are suitable for introducing transgenes at specific chromosomal locations via homologous recombination. Transformed ES cells are combined with blastocysts from a non-human animal. The ES cells colonize the embryo and in some embryos form or contribute to the germline of the resulting chimeric animal. See Jaenisch, Science, 240, 1468-1474 (1988) (incorporated by reference in its entirety for all purposes).
Alternatively, transgenic animals can be produced by methods involving nuclear transfer. Donor nuclei are obtained from cells cultured in vitro into which a human alpha synuclein transgene is introduced using conventional methods such as Ca-phosphate transfection, microinjection or lipofection. The cells are subsequently been selected or screened for the presence of a transgene or a specific integration of a transgene (see, e.g., WO 98/37183 and WO 98/39416). Donor nuclei are introduced into oocytes by means of fusion, induced electrically or chemically (see, e.g., WO 97/07669, WO 98/30683 and WO 98/39416), or by microinjection (see WO 99/37143). Transplanted oocytes are subsequently cultured to develop into embryos which are subsequently implanted in the oviducts of pseudopregnant female animals, resulting in birth of transgenic offspring (see, e.g., WO 97/07669, WO 98/30683 and WO 98/39416).
For production of transgenic animals containing two or more transgenes, the transgenes can be introduced simultaneously using the same procedure as for a single transgene. Alternatively, the transgenes can be initially introduced into separate animals and then combined into the same genome by breeding the animals. Alternatively, a first transgenic animal is produced containing one of the transgenes. A second transgene is then introduced into fertilized ova or embryonic stem cells from that animal. Optionally, transgenes whose length would otherwise exceed about 50 kb, are constructed as overlapping fragments. Such overlapping fragments are introduced into a fertilized oocyte or embryonic stem cell simultaneously and undergo homologous recombination in vivo. See WO 92/03917.
Nonhuman homologs of human genes of the invention can be disrupted by gene targeting. Gene targeting is a method of using homologous recombination to modify a mammalian genome, can be used to introduce changes into cultured cells. By targeting a gene of interest in embryonic stem (ES) cells, these changes can be introduced into the germline of laboratory animals. The gene targeting procedure is accomplished by introducing into tissue culture cells a DNA targeting construct that has a segment that can undergo homologous combination with a target locus and which also comprises an intended sequence modification (e.g., insertion, deletion, point mutation). The treated cells are then screened for accurate targeting to identify and isolate those which have been properly targeted. A common scheme to disrupt gene function by gene targeting in ES cells is to construct a targeting construct which is designed to undergo a homologous recombination with its chromosomal counterpart in the ES cell genome. The targeting constructs are typically arranged so that they insert additional sequences, such as a positive selection marker, into coding elements of the target gene, thereby functionally disrupting it. Similar procedures can also be performed on other cell types in combination with nuclear transfer. Nuclear transfer is particularly useful for creating knockouts in species other than mice for which ES cells may not be available Polejaeva et al., Nature 407, 86-90 (2000). Breeding of nonhuman animals which are heterozygous for a null allele may be performed to produce nonhuman animals homozygous for said null allele, so-called “knockout” animals (Donehower et al. Nature 256:215 (1992)).
X. Variant Proteins Some of the polymorphic sites of the invention are characterized by the presence of polymorphic forms encoding different amino acids. Such polymorphisms are referred to as non-synonymous indicating that the different polymorphic forms are translated into different protein variants. The invention further provides such variant proteins or fragments thereof retaining the activity of the full length protein in isolated form.
XI. Methods of Treatment Compounds having activity in modulating a gene of the invention can be used in methods of treatment or prophylaxis of depression optionally in combination with other treatments, particularly an SSRI.
A compound can be administered to a patient for prophylactic and/or therapeutic treatments. A therapeutic amount is an amount sufficient to remedy a disease state or symptoms in a patient presently having symptoms of a disease, or otherwise prevent, hinder, retard, or reverse the progression of disease or any other undesirable symptoms. In prophylactic applications, a compound is administered to a patient susceptible to or otherwise at risk of a particular disease or infection but not currently having symptoms of the disease. Hence, a “prophylactically effective” amount is an amount sufficient to prevent, hinder or retard a disease state or its symptoms. In either instance, the precise amount of compound contained in the composition depends on the patient's state of health and weight.
An appropriate dosage of the pharmaceutical composition is determined, for example, using animal studies (e.g., mice, rats) to determine the maximal tolerable dose of the bioactive agent per kilogram of weight. In general, at least one of the animal species tested is mammalian. The results from the animal studies can be extrapolated to determine doses for use in other species, such as human beings for example.
The pharmaceutical compositions can be administered in a variety of different ways. Compounds can also be administered as a composition containing a pharmaceutically acceptable carrier via oral, intranasal, rectal, topical, intraperitoneal, intravenous, intramuscular, subcutaneous, subdermal, transdermal, intrathecal, and intracranial methods. The route of administration depends in part on the chemical composition of the active compound and any carriers.
The components of pharmaceutical compositions are preferably of high purity and are substantially free of potentially harmful contaminants (e.g., at least National Food (NF) grade, generally at least analytical grade, and more typically at least pharmaceutical grade). To the extent that a given compound must be synthesized prior to use, the resulting product is typically substantially free of any potentially toxic agents, particularly any endotoxins, which may be present during the synthesis or purification process. Compositions for parental administration are also sterile, substantially isotonic and made under GMP conditions. Compositions for oral administration need not be sterile or substantially isotonic but are usually made under GMP conditions.
EXAMPLES The Examples describe association studies to identify polymorphic sites having alleles associated with response to treatment with an SSRI or placebo.
1. Samples The DNA samples used in the study were collected from 1,024 Caucasian subjects across eight MDD Phase II, III and IV clinical trials. Among the total cohort of samples, 511 were SSRI treated and 513 were placebo treated. The study sample comprised 652 females and 372 males. These samples were equally divided into two sets by matching based on treatment group, gender, clinical study, and investigator site. The two sets of samples are designated as primary analysis and replication analysis set, respectively.
The primary scales used to diagnose MDD patients and to measure response to treatment are the HAM-D scale (Williams, Archives of General Psychiatry, American Medical Association, August 1988, Vol. 45, Num. 8, pp. 742-74) and three sub-scales that capture different aspect of depression (Table 1), as well as the Clinical Global Impression of Improvement (CGI-I) for binary definition of responder and non-responder.
TABLE 11
Individual items for each subscale considered
Questions
Ham-D subscale (i.e. item #s in HAMD scale)
Depression (Core Lilly) 1, 2, 3, 7, 8
Anxiety 10, 11, 12, 13, 15
Insomnia 4, 5, 6
2. Genotyping The subjects of both sets were each genotyped for about 250,000 tag SNPs in a whole genome scan study (Hinds et al., Science, Vol. 307, 1072-1079 (2005)). These SNPs were selected based on the linkage disequilibrium structure of the human genome. The resulting genotype data quality checking was performed using the standard quality control (QC) procedures (Maraganore, Am. J. Hum. Genet. 77:000-000 (2005).
3. Analysis A variety of statistical models were employed to investigate associations between SNPs and both binary and quantitative response variables involved in MDD phenotypes, anti-depressant SSRI and placebo response, as well as time-to-response. In the primary analysis of the whole genome scan, linear regression and logistic regression were used. In the replication analysis, analysis of covariance (ANCOVA) model, as well as Fisher test and Bonferroni correction and False Discovery Rate (FDR) were also calculated. In these analyses, statistical significance was assessed using the q-value approach (Storey et la., (2003) Proc. Natl. Acad. Sci. USA 100 (16): 9440-9445.6), a method based on an assessment of the overall false discovery rate of the experiment.
In addition, FDR analysis was performed on 11 CNS genes that were chosen a priori based on literature reports.
The statistical procedure, model and covariates, and response variables for the depression and subscale association analysis are briefly summarized in Table 12.
TABLE 12
Analysis procedure to find marks associated with MDD or a subscale phenotype
Population Model Response Covariate Test
Male, female, ANCOVA Quantitative Age, Compare full (with
SSRI treated, measurement of gender, genotypes and
placebo treated groups Total HAM-D study interaction terms
combined or subscale included) and reduced
scores at (without genotypes)
baseline model to determine
SNPs involved in
MDD phenotype
Follow-up significant
SNPs to determine
interaction with gender
The statistical procedure, model and covariates, and response variables for SSRI and placebo treatment analysis are summarized in Table 13.
TABLE 13
Analysis procedure to find markers that are associated with SSRI treatment
response or placebo effect
Population Model Response Covariate Test
Male, female, ANCOVA HAM-D total and Baseline Type III test of
SSRI treated, Subscale score total, genotype by
placebo treated delta changes Study, treatment interaction
groups combined from baseline Age, Contrast tests to
Gender, estimate the separate
Treatment marker effects for
Binary response: Study, SSRI and placebo.
Responder or Treatment
non-responder
(based on CGI-I 1 or 2)
Results In the whole genome association analysis, SNPs with significant associations in both primary and replication data sets were observed. These SNPs were annotated as CNS-relevant or novel (i.e., not previously known to be expressed in the CNS) based on review of literature and various databases. Table 14 lists the numbers of SNPs that were assessed as potentially associated.
TABLE 14
Significant SNPs associated with MDD and/or SSRI/placebo responses
Placebo Response SSRI Response
Response variable CNS relevant Novel CNS relevant Novel
Binary 3 168 10 168
Quantitative 6 146 10 142
Time to response 1 153 8 129
The data from the analysis are summarized in the Tables that follow. In the whole genome association analysis, SNPs with significant associations in both primary and replication data sets were observed. These SNPs were annotated as CNS-relevant or novel based on review of literature and various databases.
In addition to the whole genome analysis, a priori hypothesis testing was performed on both the primary and replication sets of samples on a list of 11 CNS genes (BDNF, COMT, DRD2, DRD3, DRD4, HTR1A, HTR2A, SLC6A2, SLC6A3, SLC6A4, TPH2) that were reported in the medical literature. The significance is based on the multiple comparisons to only the SNPs within the 11 CNS genes tested. Among the SNPs located in these 11 genes, the most significant result was for the Total HAMD end-point for SSRI treatment response for SNP 1752273 located within the gene TTC12 on chromosome 11, within 50 kb of the well-known dopamine receptor D2 (DRD2). This SNP is a part of a 3 SNP haplo-block that are in high LD This SNP which is located in gene TTC12 adjacent to DRD2, and two other adjacent SNPs sharing the LD bins are listed in the table “CNS_relevant_CNS.txt”.
The SNPs meeting the significance level and FDR level are listed in the tables described below.
A. CNS a Priori and CNS-Relevant Category For the a priori hypothesis testing and the CNS-relevant genes categories of SNPs, the results are provided in Tables 2-4. In these tables, the SNP association results are organized by the primary objective categories and types of analysis into separate work sheets. The first table (CNS_relevant_CNS.txt) contains results from a priori hypothesis testing on the 11 CNS candidate genes, and the other six tables contain results from the whole genome association study for only those SNPs that could be annotated to CNS-relevant genes based on public literature and databases.
B. Novel SNP Category For the novel categories of SNPs, there are 6 tables, Tables 5-10. Table 5 relates to linear genotype (i.e., SNPs associated with placebo effect by a linear measurement). Table 6 relates to binary genotype (i.e., SNPs associated with placebo effect by a binary measurement). Table 7 relates to binary interactions (i.e., SNPs associated with SSRI effect by a binary measurement); Table 8 relates to linear interactions (i.e., SNPs associated with SSRI effect by a linear measurement). Table 9 relates to time genotype (i.e., SNPs associated with placebo effect by a time measurement). Table 10 relates to time interaction (i.e., SNPs associated with SSRI effect by a time measurement). Each of the tables is divided into four subparts (A, B, C, D) corresponding to the four scales of the HAM-D phenotypes HMDT: Total HAM-D, CLILLY: Core depression, ANX: Anxiety, and INSOM: Insomnia. Tables 5-10 contain the associated SNPs that were not annotated to CNS-relevant genes as described above. Fisher Pval is Fisher's method for combining the main p-values from the two sets and FisherQval is the estimated False
Various embodiments and modifications can be made to the invention disclosed in this application without departing from the scope and spirit of the invention. Unless otherwise apparent from the context any embodiment, feature or element of the invention can be used in combination with any other. All references including patents, patent publications, applications, SNP or sequence identifiers or the like and journal articles cited herein are incorporated by reference in their entireties for all purposes to the same extent as if each were so individually denoted.
TABLE 1
chro-
mo- ref— alt— ref—
snp_id dbsnp_id some accession position base base flank freq genes_near
10940 rs2823731 21 NC_000021.4 16566315 A G ATACATTATATTTAAACATATCTCTATAGAGTCAACAAAATAAAATAAACA 0.5986 VDAC2P-[LOC388815]-LOC391270
12394 rs2823937 21 NC_000021.4 16947265 A C ATGTAAGATCGTTTGGGAAAATGTTAAGACAGATATCTTGCTTTAATTTTT 0.6183 LOC388815 [ ]-LOC391270
17207 rs2824839 21 NC_000021.4 18746350 C A GCTTATGTTTATGTGATGGCACCTGCGAGTACATAGAGGTTGGATATGTTA 0.5494 PRSS7 [ ]-LOC388816
17255 rs2824848 21 NC_000021.4 18775552 T C ACTCCAACCCACAGCATTATTATTATTCAGTAGGTTATAGAGGTGTTATAC 0.5109 PRSS7-[ ]-LOC388816
20802 rs2825756 21 NC_000021.4 19999393 A G ACCCCTTAAATTTTCATTTTCTCTCAAAGTCTCCTCTAAATTTAGTATATT 0.8111 SLC6A6P-[ ]-C1QBPP
39641 rs928261 21 NC_000021.4 25378214 T C TGATTAGCCTTCCATTTCATAAACCTTTTTTTCCCCTGGAATTGATAATGG 0.3077 LOC400860-[ ]-LOC284821
40257 rs2829674 21 NC_000021.4 25557670 C T ATAAAGTTGGAATTTGGAGTCATGGCCTGAAAAATGTGAGCAAGTAAAGAA 0.5755 LOC400860-[ ]-LOC284821
54303 rs2832046 21 NC_000021.4 29038677 T C TGGAAGGGTAGAACCTTAAGTAGTTTTTCATTCTCTGACTACTCAACTAGA 0.8541 C21orf100-[ ]-C21orf127
75560 rs2226829 21 NC_000021.4 36987160 T G GATTTTGAGGCCATGTTTCCGTTAATCTGGACCGAGAGCCCTCTGGGAGAG 0.311 LOC388823-[ ] SIM2
76470 rs2835628 21 NC_000021.4 37439923 A G AATGCGATTTGATGATTGTAACAGGACAAAATTTTGATTCTTTCGAAATTC 0.2715 DSCR5-[TTC3]-DSCR9
82434 rs2836671 21 NC_000021.4 39052714 G A AGCTAGGTGGTGTTCTCGTGTACATGTTAGAGATGAGGAAACCCAATCTCT 0.6101 ERG-[LOC400866] ETS2
104324 rs1296754 22 NC_000022.5 16360114 G A TCCTTGTTTCCCCCAGCCTTTTGTCGCTTAACATGTTTCTTTATGCTTATT 0.3001 CLCP1-[CECR2]-SLC25A18
120178 rs465736 22 NC_000022.5 28159320 A G GTTCTAGAAGTGACAAAGCTGGGACACAATACCTTTATGCATGAAAAGGTT 0.8434 AP1B1-[RFPL1] NEFH
120634 rs740041 22 NC_000022.5 28524653 A G CATCTCTCTTATCATGCTGCCTCCCAACATGCAGGGGAGAGTCCTGGCCTT 0.601 HSPC051, LOC55954 [ASC1p100]-
MTMR3
120658 rs2074707 22 NC_000022.5 28534910 G A CTGAATAAATGGCTCAATGAATAACGCACAAGTGAACATGTCAAACTGAAA 0.6 HSPC051 [ASC1p100]-MTMR3
120666 rs17711377 22 NC_000022.5 28537540 C T TTTGGGCAGGTCTGTCCTTGGTTTCCTTATCGATGACCATGCAGCCCTTGC 0.5875 HSPC051 [ASC1p100]-MTMR3
120843 rs2285667 22 NC_000022.5 28708658 T A AGCAAGAAAAGATTACTGTTCTGGCTCCCTTCAGCTTCTATGTCATTGCAT 0.6244 ASC1p100-[MTMR3] LOC400924
120880 rs41157 22 NC_000022.5 28729705 T C CTTGGCCTTGGCTTTCATTTTGCATTGCTCTTAAATAATAAGTTTGCTTCT 0.3814 ASC1p100-[MTMR3] LOC391326,
LOC400924
120906 rs41168 22 NC_000022.5 28742715 A C CTCAGCCCCTGCTCTGAGTGCCATCAATTTAACTGTTTTGTGGTTCTTCTC 0.3829 ASC1p100-[MTMR3] LOC391326,
LOC400924
121018 rs1548389 22 NC_000022.5 28898106 T C AAAGGTATTGGACTTATATCCTTGATAGAATTGTAGACTGAGTCACTATAA 0.5895 MGC26710 [ ]-LIF
133091 rs34770535 22 NC_000022.5 36928983 T A TCCATCCGCTTCCCAGGCAGACCTATCAGCCAGACAGCTTCCGTCTTGCCT 0.9712 C22orf5 [ ] CSNK1E, LOC400927
137315 rs926350 22 NC_000022.5 41702889 C T TAGAGGCAGCCATCAAATCACCACCCGGGAATGTTCAACTGCAAGTGTGCC 0.7844 PACSIN2-[TTLL1] BIK
137829 rs5996341 22 NC_000022.5 42090418 C T GGAGATTTCCTTGACTTCGTCTTCCCTCTTTTGGTCAAATTAAAAAATATC 0.5363 SCUBE1-[C22orf1]-FLJ23588
138564 rs16991431 22 NC_000022.5 42742499 C T ACCCAGGAGGGCTTCTTGGAGGAGGCGGCCAGTAAGATGAGGTTGAAGATA 0.7787 CGI-51-[PARVB]-TRSPP1
145360 rs6007770 22 NC_000022.5 46571750 A G CACCCCACACTGGACACATCCTTATAGGCACTGAGACACTTCTGGGAGCAC 0.8837 LOC400932-[ ]-LOC388914
159809 rs4127784 14 NC_000014.4 26997334 C T CATCTTACAGAGTGAAGTGCCTGATCCTAAGATATGGTGGTCAAAGAGGAT 0.5709 RPL26P3 [ ]-BTF3P2
159815 rs12882372 14 NC_000014.4 27002793 G A GTGCCTGGCCTACGATTTTAATTACGGTAGATTTATATTACACTTAAACCT 0.6128 RPL26P3-[ ]-BTF3P2
160343 rs17114346 14 NC_000014.4 27343901 G C GTATTTTCTTTTAACTTTCAAAACTGTTTTTGCTCCAAAGAACAAAAGCAA 0.9947 LOC387978-[ ]-PRKCM
162110 rs2819780 14 NC_000014.4 29261783 T C GCTGGAGAGGCAAAGTTGGGACAAGCATATTTCTATATTTCTTAGTATAAG 0.973 RPL12P5 [ ] RPL27P1
163068 rs225940 14 NC_000014.4 28516976 G A TCCTAATCAGTGGGACTTTAAGAGTGCTTTAAGGGCAATATTCCTATTATG 0.4135 PRKCM-[ ]-CBPINP
169827 rs10129645 14 NC_000014.4 35848871 A C AGACTAGAGAGACTAAAACAGTTGAAGTGAAGAACCTGAAAGGAGAGCTTA 0.7576 SLC25A21-[MIPOL1]-FOXA1
178191 rs10483614 14 NC_000014.4 51141466 T C CAAATGTTTAAAGCTAATGTCTTAATGGTATGTACTAAATCAAGCTACTAA 0.8227 DKFZp762F0713 [ERO1L] STYX,
PSMC6
195161 rs10143275 14 NC_000014.4 67131529 A G AATGGGGCATATGTTCCATAAGTAGACCAGGGGTATCACCAATGAGCGTCT 0.2865 RAD51L1-[ ] RPL12P7
208445 rs880373 14 NC_000014.4 76732331 G A GTCTACCTCTTACCTTTGCCATTTCGTTCTGTCAATCAGAATTGAGTCCAG 0.8337 FRDAP-[ ]-NRXN3
214385 rs1955427 14 NC_000014.4 83914088 G A CCTACCTTCTTCGCTCCCTAGCTGCGTTTATTTAACTTAGTTCAGAGGCTT 0.7949 RNU3P3-[ ]-LOC283583
222093 rs732171 14 NC_000014.4 88905407 T C CACACACAAAGATGAAATGAACTCCTTTGTCGTGTAAGAATCTCTCCAACG 0.8442 CALM1 [ ] LOC400238
238656 rs11625351 14 NC_000014.4 101746762 A G GTGGACCAAACAGAATCCAGGCTCCAAGCCTCTCCCTGGCAAGCCTCTTGC 0.4456 RPL21P13, RPL17P4 [ ] LOC388019,
EIF5
256781 rs9368147 6 NC_000006.6 10345221 T C CAGCCTTTGTCTCCTGCACAGGTACTGTTCGCTACTCTTAAGGATGCAAAA 0.8468 OFCC1-[ ]-TFAP2A
269181 rs17320151 6 NC_000006.6 18844754 A G ATCAGAACTTACAGAACACTTTTAGAGTAGATATCAGAGAAAAATTCATAG 0.4911 IBRDC2-[ ]-ID4
272259 rs851601 6 NC_000006.6 66889451 G A CTTTTCAAGTGGACTTGTAAAAATCGAAGAGAAAAATGCAAAGTTTCCCAA 0.2565 NUFIP1P-[ ]-BAI3
279774 rs6920211 6 NC_000006.6 135411888 T C GGTTCCATTGAGACTGATGCTGCATTGAATTCTGATGATACAGTTCGCTGC 0.7901 HBS1L-[ ]-MYB
280097 rs728030 6 NC_000006.6 135226864 C A GATTTGTATACTATTGAGGTATTAACGATCCATATTTAACCAAGTGTTTTC 0.3688 LOC154094 [ALDH8A1] HBS1L
280907 rs567049 6 NC_000006.6 149602520 A G GGGGGTGAAAGGAGTCCATACCATTAGTTCTTAGCTTCAAGACCTAAATCA 0.615 UST-[ ] MAP3K7IP2
283793 rs1099652 6 NC_000006.6 167139812 G A GGTCACCTCAAACCATGATTCAAATAAGGCAGATTTTGAGTTTGTGCATAA 0.8295 RPS6KA2-[ ]-RNASET2
289615 rs9260980 6 NC_000006.6 30067845 A G CAGGGTAAATTCCTGTAAGGCCTGGATGCCCTGCTGTGAGGTCAAAGGGGG 0.867 HLA-A, MICD, HCG9, HLA-
80, HCP5P3, HCG2P6, HCG4P4 [ ]
HLA-J, C6orf12, ETF1P1, HCP5P2,
3.8-1.2
295720 rs9364688 6 NC_000006.6 163810679 A C AGTGCGTGGTTAGCTGTGTTAGACCAGTACGCTGAATCGCTTTGTGGAACT 0.4757 LOC401283-[QKI]-C6orf118
302732 rs581785 6 NC_000006.6 54001550 T C CTTAAGTCTCTGAATTGAGCTTTCTTATAGCAGTAGGGTCCTCATCGTCTG 0.0946 LRRC1-[C6orf142]-TINAG
303552 rs12055820 6 NC_000006.6 24077292 T G ATAAGAAAAAGCATGCAGAGATACATGCAGACTTGAGAAATCGATGGCATT 0.751 LOC401238-[ ]-VMP
313699 rs9373149 6 NC_000006.6 136025972 C A ACCTCATATACCTTGTATCCAGAAGCAACCAGGTCATCTCTTAGCATTTTC 0.6896 AH1-[ ]-PDE7B
313717 rs1475069 6 NC_000006.6 136036804 A C GCAATCAATGGAATTTGCAAGTGCGAGATGAATTTTCCTTAATTAAAATCT 0.6985 AH1-[ ]-PDE7B
320863 rs1572674 6 NC_000006.6 140244804 C A GGCTCACTTTAGGGTCCAGGAGAAACAATATGGAAACCAGTAAAGCTTTTT 0.88 LOC340148-[ ] LOC401276
331584 rs6458829 6 NC_000006.6 52238093 T C GCCTAGCCTGATCTTCAACCTTGTCTGTTCTCCAGCTATAGATGAGAGTCT 0.9502 MCM3 C6orf33
334643 rs9486657 6 NC_000006.6 107974946 C T GGACAAACATCTTACATCTTATACACCATGGTTTTGTTCAGAACTGGGCTT 0.7184 C6orf210-[ ] FLJ10159
340241 rs4945651 6 NC_000006.6 120164665 A G CTTCTTATCTTACTGGGGTAATCCAATTATGACTTGTACCTGCTCTGGCTT 0.7778 MAN1A1-[ ]-C6orf170
342860 rs199638 6 NC_000006.6 72232763 G C AGGGGGAGACCTAATTATCTGGGCTGTCCTTCAAGATCCTTCTCTTTCTTT 0.2344 C6orf155-[ ]-RIMS1
343816 rs9360051 6 NC_000006.6 94782633 A G AATAAGAACATTTTGAAAAATAGGTAAGAATTTAAGCCCATCAACATAAAA 0.9105 EPHA7-[ ]-HCP17
348386 rs17717044 6 NC_000006.6 82737724 G C TCTAGGGAATGTGATTTAGGATTAAGTTCTCAAGTACTTTTTTTTGCAATA 0.9595 LOC389413-[ ]-IBTK
350246 rs9320552 6 NC_000006.6 116355906 C T GGCCAAATTGATAATATATACAATCCAGTAGCTTTGTTAGTTATTCAAGCA 0.6471 HS3ST5-[FRK]-NT5C2L1
355828 rs9375582 6 NC_000006.6 128938976 T G TTTGTAACTTCCTTGAAGGCAGAGTTTCTTCTTCGGGTTTGTATTATCTAT 0.8004 PTPRK-[ ]-LAMA2
358303 rs2806719 6 NC_000006.6 116865194 T C ATTTTCCCCTAATTATCACAAATAATTTAAAATTACATGGATGCCTCATTA 0.0413 SART2-[ ] C6orf188, C6orf78
358756 rs615199 6 NC_000006.6 117159223 T C TTAATATGACAATAATCTCCACAGCTGGTACATATTTGCCAAATGTGGTAG 0.684 KPNA5-[GPRC6A]-RFXDC1
363483 rs10949074 6 NC_000000.6 57381100 C T TGAAGAAGCAGGTAGAACACTGTGACCTTACGATGTGAATTCTCTAATCAG 0.7415 RAB23-[PRIM2A]-LOC389401
365290 rs3799070 6 NC_000006.6 69959617 A C ACACCCTTTAACTTTATTTACAGTAAATGAGAGCAAGTTTTAAAAGCCTTT 0.786 NUFIP1P-[BAI3]-C6orf209
368144 rs4840208 6 NC_000006.6 102686804 C T TTATTGTAGTACATTGAAAGAAACACGAATAAACAGGAATATACCATTCAA 0.4766 GRIK2-[ ]-LOC389419
383165 rs1883324 6 NC_000006.6 11914419 G T TGTGAGCCCCTTTTGTCATTGTCAGGGCCTAAGGGTCCAGGAATCACTGTC 0.6534 C6orf105-[ ] LOC389369
383212 rs1569731 6 NC_000006.6 11933400 A G GAGGGGAAATTCCAAGCTGCAGAGTACGTGAAAACAGTTTTTTAAAGTTGA 0.7302 C6orf105 [LOC389369]-HIVEP1
383214 rs2143715 6 NC_000006.6 11934194 T C CATTCCATGTTCGTCCTGAGGTAAATTAGCCTAAGTGATTATTGTATCAAA 0.7308 C6orf105 [LOC389369]-HIVEP1
389068 rs1571913 20 NC_000020.6 46813492 T C TGTATTGGGAGTGCCCTGTAGAGGATGAAAGGGAGAGAAGCAAGGAGAGTA 0.0054 RPL35AP [ ] NCOA3
396080 rs17123518 20 NC_000020.6 31993265 C T GGGAGCTCACACCTTCGAGAGGCCACGCTGCTGCCGAAAAGAGGGGCTGCT 0.9593 FLJ33706 [ ] COMMD7
406464 rs4396776 20 NC_000020.6 17048777 C A TGAAATTGTGGGTATCACATGGGATCCTTAGGAGCAGAGTATAAGCACAGA 0.5296 OTOR-[ ]-PCSK2
407964 rs16823 20 NC_000020.6 17786064 G A GTCGCCCACGGTGGTCACATGATCAGTCCTGGTCTTTATACCATTACTTCC 0.8016 C20orf179-[ ]-SNX5
409576 rs6035200 20 NC_000020.6 19017894 A T CCTTTTGGAAAAAAAATCATGTGTCATCTCCATTATACTGAACTCTCTGCA 0.6532 C20orf79-[ ]-SLC24A3
411305 rs6081854 20 NC_000020.6 20037883 G A ACAAGACACATGAGGGAAAAAAACCGTCTTGGAGGTTCTTGCCCCAACAGA 0.4435 NAT5, CRNKL1 [C20orf26]-RPL17P1
414780 rs2301020 20 NC_000020.6 49389941 A G GACATACACTTTCTTCCAATTCTGGATATATTTGTGTGCACACAGGCTACT 0.5338 LOC149738 [UBE2V1, Kua-UEV] Kua
428043 rs2425501 20 NC_000020.6 41963754 C A GGAGTATGGGAAGGTCCTGAAAGAGCCCCTAAGTTATGCTTGATTTACTGC 0.5802 LOC391249-[PTPRT]-PPIAL
437310 rs6040221 20 NC_000020.6 10861996 G A CAGAAAATCATCTTTTCAGGCTTAAGGTGATCCTCAAAATCAGAAAAAAAC 0.4245 JAG1-[ ] FAT1P1
441242 rs6109927 20 NC_000020.6 13508267 A G TTTTACGGAAGTATTTCTTTTGCTCAGGACAGTTCTAAGTGCAGTGGCAGA 0.6658 MRPS36P6-[C20orf13]-C20orf6
446808 rs2870357 20 NC_000020.6 54006326 G A TTCAGTCTCCACCTTTTAGAATTCAGACCATTATCTGCGGTTTTGGATAAT 0.5479 DOK5-[ ]-RPL12P4
456564 rs728265 20 NC_000020.6 881379 G A TCCAACCAACTCATTCAGATGTGCCGAGACCTGGGCATGGTGCTGGGGATA 0.8092 C20orf55-[ANGPT4]-LOC343637
470618 rs17155560 7 NC_000007.8 81078793 G A GGAAGAAGCCAAAATAAACAGAGATGAACAGACATAAAAAGAAATTATAGC 0.6565 HGF-[ ]-CACNA2D1
472520 rs6943619 7 NC_000007.8 105765830 A G TATATGGTGGTTCTTCTTCATTTCAATCTCAGAGGATAACTTTCTAAATTC 0.3746 PBEF1-[ ]-FLJ36031
481459 rs7801675 7 NC_000007.8 18882744 G C CTCAGATAAATTCATTTAAGTGGCTGAGGAACACAGCTAATAATTGGCAGA 0.8295 HDAC9-[ ] TWIST1, FERD3L
486447 rs13222512 7 NC_000007.8 25263122 T A ATTATTTTATTTCATGCAGTTACATTTATTTATTCAGCAAATATTTATTGA 0.7984 C7orf9-[ ]-UBA52P1
492423 rs9718390 7 NC_000007.8 29071360 G C AAAGGCCAGCAGGACTACGGGTTAGGCATGAGTAAGCCGACGGGAGAGGGA 0.6501 LOC401318-[CHN2]-LOC222171
497179 rs2214882 7 NC_000007.8 40767209 A G GCCATTATGCAATTCTCCCTAACTGAACTACCTTTCACCTTCATCTCTGCT 0.2157 C7orf10-[ ]-INHBA
499954 rs17134115 7 NC_000007.8 50783028 C T GTGCACAACTGTCAAGTTTATGAGACGACTTGAGGTTTGCTGTTGTCTCAA 0.9462 GRB10-[ ] COBL
502021 rs17169536 7 NC_000007.8 16318284 G A ACTGGCCTCACCTTATAATGTAACAGCCCATTATTGATTTAGGACAGGTTT 0.6804 SOSTDC1-[ ] LOC317727
502183 rs2301971 7 NC_000007.8 16255401 A G ATAGCACCTGTTAAATGGAAAAGTGATTAGCTATTATAAGTTTAGAAAAAA 0.7038 SOSTDC1-[ ] LOC317727
507206 rs11344954 7 NC_000007.8 81180842 G A GTGGGAGTTGTGTTCAGCCGCAAAAGAAAATGAATTAGTGTGTTATATTTG 0.5191 HGF-[ ] CACNA2D1
507284 rs37089 7 NC_000007.8 81222775 G A AGCAAGAGAAGCTTCTCAAGGATACGGGCATTCAAAAAGCCAAGAATAGGC 0.7225 HGF-[CACNA2D1]-PCLO
509722 rs36068462 7 NC_000007.8 87862275 A G GGTCAGATAATATCATCCAAACCACATGAATGGAACACTGAGATACTGCTA 0.3996 LOC392069-[ ] LOC219558
516338 rs4729988 7 NC_000007.8 103468701 C A TACTGATAGTTACAGCTACTATATACAATTCAATTGACTTCCTCAGGATTA 0.7117 ORC5L-[ ]-LHFPL3
519293 rs4730253 7 NC_000007.8 106921967 A G TAACGAGAAGCCTTATATACTACATAAAGGAGCCTAGGTTTTATCCTCCAG 0.2889 SLC26A4 [ ] SLC26A3, CBLL1
522335 rs9649349 7 NC_000007.8 111226234 A C ACATAAAACCCTTCAATGGATCCTCAAGACCAATGAAATAAAGTGCTAACC 0.5962 LOC402295-[DOCK4]-ZNF277
523650 rs39311 7 NC_000007.8 116508620 T G CCCAGGGACCTTTCAATTTTATGCTTATCTTTCTTTATATATTAATATCAA 0.7317 LOC402296 [WNT2] GASZ
526026 rs34624434 7 NC_000007.8 119115798 C A CCTGAAATCAATCTTAAATTTTCAACTTGTTTTCCTCTACACTGTCACTAC 0.8411 ANKRD7-[ ]-KCND2
528496 rs2237794 7 NC_000007.8 126346076 G C TCAAATTAAGGGGATCATCAACAACGTTTTCTACAGTTCACATAGGAGGCG 0.7806 LOC401398-[GRM8]-LOC346646
532395 rs2301896 7 NC_000007.8 143076729 C T TTTCTGAGAAGGCCTTAAAGAAAATCATGGTATACTTAGAATTATTGGACA 0.6507 OR2F1, LOC346524 [ ] LOC135944,
LOC135946
539841 rs2267706 7 NC_000007.8 139103545 G A TGCGATACCATCTCCCCACTTCTACGCCAAGCTGCTCACGGTCTCACCCAG 0.7513 LOC389562-[TBXAS1] ZC3HDC1
542193 rs3901848 7 NC_000007.8 30548185 G A CAAGGCCGTCTAAATTGTCCTTCCAGTGTAAAGTCCATTGAATTTTTCTCC 0.4635 INMT, LOC402254 [ ] FLJ22374
552812 rs17286418 7 NC_000007.8 15881856 C G TAAATTACTAATATGTAGCACCTTGCAAGTGTATAAGTGGTCAACTTTATA 0.632 MEOX2-[LOC402250]-SOSTDC1
552869 rs35150436 7 NC_000007.8 15931275 C T ATGCAAAATCCCTGGCTTCAAGGAACGCATTTCCCTGATGCAGGCCACATG 0.6557 MEOX2-[LOC402250]-SOSTDC1
552991 rs17153388 7 NC_000007.8 105909694 C A CGAACCAGTTGATTTTGTTTGCATGCATGAATTTACATGTCCTTTCAACAG 0.6769 FLJ36031 [ ]-LOC340340
555251 rs1003404 7 NC_000007.8 68467077 T C TGTCTTTATCTGCACTATAAAATACTGCAGCCTAGCTGGATGAGACGGTTA 0.154 FLJ13195-[ ] AUTS2
555297 rs10487947 7 NC_000007.8 68416498 G A GTGCCCAGCCCCTGGTGATTTTATGGAGAACTTACTCTGTGCCCTTGGATA 0.8703 FLJ13195-[ ]-AUTS2
555302 rs17140651 7 NC_000007.8 68407681 G A TACAAGTATGATAGCATCAAACACAGGGCTTAGTTTGCATGCCCTCTTATA 0.8691 FLJ13195-[ ]-AUTS2
555380 rs6967772 7 NC_000007.8 122605855 G T TTTCTGGTTTCAATCCAGTGAAAGTGCTCTTCAATTCTCTACCTTTTGCCA 0.8383 SLC13A1-[ ] FLJ35834
561917 rs2041357 7 NC_000007.8 22840820 A G TTGAGCAATTTCAGGACAGCAGTTTATCTTTTGGTCTGAGTTGTTTGGAGT 0.7383 DRCTNNB1A [ ] SBB126
583132 rs17167392 7 NC_000007.8 133121089 G C ATAAGAATTTCCCTATCAGCTACAGGGTCTCTTGCAGGGAAATTGTTTTAA 0.8063 FAM10A7-[SEC8L1]-FLJ32786
583166 rs12669887 7 NC_000007.8 133145749 T C GTCAACATTTTTGTCTCCCCAAGCATTTTCTGATTTGAACTATTTTCTCAC 0.7991 FAM10A7-[SEC8L1]-FLJ32786
594176 rs12154667 7 NC_000007.8 92790831 C T TTAAAATACTCAGCTTAGGAAGTTGCTGTTAAATAACATAAAGACAATTAC 0.5109 CALCR-[ ]-LOC346588
594210 rs13237782 7 NC_000007.8 92799057 T C GTATCATCTTGTGTTTCTCCTAGTGTATCAATATTTGTTTCTGAGTATGAT 0.6046 CALCR-[ ]-LOC346588
603200 rs2033047 7 NC_000007.8 37270115 T G AAATAGCCTTGATAAAATGAAAAGATCCCTAATTGTGGCAGTTGGAAGTTT 0.4847 ELMO1 [ ]-LOC340285
607843 rs713504 11 NC_000011.5 16964299 G C AGGGAAAGAGGTGTAGCAGGCCTGAGCAAACCCAACCATGATGGGCTTTAG 0.8566 LOC390096 [ ] LOC399872
612631 rs1107162 11 NC_000011.5 112826688 A G TGGGTGTCTGAGGCCCTTGCCCCTCGCTTATCTTCTCCCAGATACATAAGA 0.598 TTC12, ANKK1 [DRD2]-TMPRSS5
617225 rs560097 11 NC_000011.5 64817890 A C GTTATTATATCAGGGTAGTAGAATAAGGGATTTTTTTTTTAATCTATTTTC 0.8621 LOC387780-[POLA2] CDC42EP2
617266 rs8638 11 NC_000011.5 64840278 C G AGGACTTGTGCAGCCGGGCCTGCCTCTGAGTGGTGCCTCTCCTGGAAGGAA 0.8548 LOC387780-[POLA2] DPF2, CDC42EP2
617297 rs630055 11 NC_000011.5 64862893 A C GGAGCTTGGCCCTGGTGGTGAGTCTATAAGATGCAGTAGGTCTTAGAGTGA 0.8614 POLA2 [CDC42EP2] DPF2, TIGD3
617524 rs7940108 11 NC_000011.5 64041560 G A GTGCAGTCCCTACACCCTGCTTCCCGCAACCATCCTCAACCCAACAGCCCC 0.5662 FLJ37045 [ ]-SLC22A11
619434 rs11032807 11 NC_000011.5 34658644 A C TTTCTCATACACAATTCAATCAAAAATTACTAGGACCAAGTGACCAAATTC 0.8406 EHF [ ]-MMRP19
622215 rs655875 11 NC_000011.5 79506694 G C TTTTTTTTTAAAGAGAATCAAAGATGAATAAGATTTAGTACCAAGTGAGAC 0.6546 LOC390227-[ ]-MGC33846
625834 rs2295756 11 NC_000011.5 35205538 T C TAGTTACTAAAGCTTCCTTCCTAAATGAATGATCACCAAGAGGACCCCATG 0.6259 PDHX-[CD44] SLC1A2
627822 rs3135056 4 NC_000004.6 2068475 C A CAGCAGAGATGTCCCAGGCTCAACAAATTTGCGACTGAACTCTTGTTCTGA 0.9281 LOC401115, FLJ37478 [POLN]-
MGC4701
632286 rs243978 4 NC_000004.6 111740752 C T CACTCTAGAGGAGTCTACTTTTCAGCGATGAGCAGGAGAATGCCAATAAAT 0.3735 LOC132707-[ ] LOC391684,
LOC391685
652898 rs10489158 1 NC_000001.5 21969871 T C CCTTACCAAATGGAGGGTCTGAACTTGGATGCCGGGAAGTTTTCTGGAAGG 0.9487 WNT4 [ ]-LOC343384
653852 rs591858 1 NC_000001.5 30393689 C T TAGTGTTTTTCAGGAGATAATGTGACTGTTTTTGCGCTAGAAAGTCATGAA 0.8238 LOC388614 [LOC388615]-MATN1
663947 rs12090000 1 NC_000001.5 174391736 A G ATGCAGTGAGCAAAATGGATTTGGCAGTGACTTAAAAAGACTTCATGTATT 0.9749 PLAC3-[ASTN, LOC57795]-LOC400796
664783 rs859413 1 NC_000001.5 172684309 G A GAAAAAAAAAACTCATTCTTACCCAGCTTACTTATTGTCAATACATAAATA 0.4077 TNR -[ ]-LOC388716
668040 rs2420178 1 NC_000001.5 68541785 A G CCTATTTATTCACTTGAGCATTCTGAATATCATTGACATTTTCTTTGACTG 0.1122 AF357533-[ ]-LOC388639
670526 rs845451 1 NC_000001.5 207508491 C T GGCTGTAATCGAAGCAGAAGTGCCTCACAAATTAACTAGCAGTCGCCCACA 0.5548 LOC400802, SERTAD4 [ ] LOC339397,
LOC199827
674238 rs12750241 1 NC_000001.5 37252821 T C GTTCAAACACCGGAAATGTCTCCAGTCATGGAAAATGAGCAAATAATGAGC 0.4822 GRIK3-[ ]-FLJ23231
679867 rs11203277 1 NC_000001.5 16680808 C T GGGCCCAGCCTGTGCACCTCGACTCCTTCCAGCCTATGCTTTCTTGCCCCT 0.2183 CROCC, LOC400742 [ ] MFAP2, SDHB,
HSA9947
690495 rs2474291 1 NC_000001.5 27352326 G T CAAGGAAGAAGCAAGTCCTTGCATAGTGATCGTTTGTGACCTAAACAACTA 0.8979 GPR3, FCN3, LOC388611 [ASF2]-
DJ159A19.3
697891 rs3766983 1 NC_000001.5 178886415 C G CCCTAATTTATTTGTGGGATAAAAACGATATTGAATATGAGAGTGGTGGGA 0.4278 LOC284646-[CACNA1E]-LOC127665
704088 rs9425465 1 NC_000001.5 169118706 T C TTATGTTGATATATTTTCCTTTTCATAACACCCTAAAATCTAGATACAATA 0.5234 LOC127099-[KIAA0820]-LOC92346
707407 rs2295633 1 NC_000001.5 46244300 A G GATGTTGTCGTCGGGGTGAACTGTGACCCTGTGGGACAAGTATATAGAGGG 0.3721 MGC22960 [FAAH] LOC388628,
LOC391036
727193 rs6436839 2 NC_000002.6 230172337 A G GTAGCAAGTGCATTCTGTGAAACAAAGATTTTTTATCATTATTATTGGCCA 0.75 SKIP-[FLJ20701]-DNER
736610 rs3732051 2 NC_000002.6 51401708 C T AGCCAAAAAAGTATCACTTAATGCACCAAAGTAATAATGAGCAAATTAGTA 0.8612 NRXN1-[ ]-CRYGGP1
739904 rs2192720 2 NC_000002.6 40221508 C T GAAAACTTCAGAGAATCTTGTGTAACGGAACAGATAATTTTAGTAAGTTAA 0.7268 LOC391368-[ ]-SLC8A1
755186 rs12993541 2 NC_000002.6 41213992 G A TCATGTAATTGGTAAAGTACCATTGGTATTTTTTCCTCATATTAGATATGA 0.6772 SLC8A1-[ ]-LOC388941
761347 rs17014806 2 NC_000002.6 34368781 T C ATTTGCAACAGCCATTCAACTCTAGTATTAGCCTAATGATATCAAAGTCCA 0.8685 LOC344371-[ ]-MRPL50P1
761361 rs17014794 2 NC_000002.6 34363274 C A ATTTGCTGAGGATATAAAGGGGAGACTGTCCAAATGCAAACCCTCAGGAAG 0.868 LOC344371-[ ]-MRPL50P1
764102 rs3770403 2 NC_000002.6 53897359 A T AAAATGTATTGTTACTTTACTACAGAGACCATTACATTGTATAGACCAGTT 0.5631 LOC388949-[ASB3]-XTP3TPB
765032 rs11904632 2 NC_000002.6 15427783 C A AGGAGGTAGGTTTGTCCAAACCATGCAAATTCTAAGGACAGCCGATAATAC 0.545 LOC400944-[NAG]-DDX1
766107 rs12990693 2 NC_000002.6 215338370 T C GTAAATTAATTTGAAGGGTAAAGTATAATTCTGATACTTTTTTGCATTTTT 0.3988 ZNFN1A2-[PF20]-LOC402117
769719 rs1424677 2 NC_000002.6 155129332 A G AAGTGGTGTTCCATGTTGCTTCCTTATTACTAAACATGAGAAACTGCATTA 0.117 REPRIMO-[GALNT13]-KCNJ3
770100 rs4669889 2 NC_000002.6 13002330 T C GCAAGGAACTCAAGACAGCCTATCTTTCTGGAAAAGTAACTGTCCAGTTTT 0.4341 TRB2-[ ]-NSE1
770116 rs4669885 2 NC_000002.6 12994758 C G ACTCCAGCTGTGTGTGATTCCTGTCCTATCTGTCTGACTACAAAGCACATA 0.4391 TRB2-[ ]-NSE1
770139 rs10164960 2 NC_000002.6 12986898 G A TGGTCATCCATTCCTCAAGCCAGCCGGAATCTCCAAGTTCATTTCTTCCAT 0.4335 TRB2-[ ]-NSE1
772518 rs13015492 2 NC_000002.6 15527455 G A CCATTCATTCCAGATGTCTCACAACGGATGACTGGCCCCAGTCACACTGCC 0.3029 LOC400944-[NAG]-DDX1
773759 rs17202778 2 NC_000002.6 208437329 T C TGCTGTTCCTCTGACAATCAATTCATTGATCTTCACCATTCCACTCCAGGA 0.8093 LOC389071 [ ]-CREB1
784172 rs7562607 2 NC_000002.6 169740134 T C GGCACTCAATTAATACTTGAAACAATGTGTGAATGAGAAGCGTGCAGTAAT 0.5558 STK39-[LOC253782]-NOSTRIN
797205 rs3804701 3 NC_000003.6 110034946 A G ACTATATCTAAACAAACCCTTAATTACAGCAGTACCACAGGACACTGTTCT 0.6342 GUCA1C [MORC]-LOC401081
799054 rs16851191 3 NC_000003.6 142283107 C T AGTGACATTTCAAGAATACCACCTTCATCCAGTCAGGCGTATGCTGAGAAA 0.8408 SSB4-[FLJ23751]-FLJ35036
800376 rs562511 3 NC_000003.6 62736442 G A ATTATAGAAGAGTTTGGAGGAAGACGTTCAGCATTTGAGCTAATATGTGCA 0.0534 FEZL-[CADPS]-LOC389127
803273 rs961155 10 NC_000010.5 117243752 T A TTTCTTCTCTGTATCACTGTTTCTATCTCTGTCCCTCTCAGTAGCACCCTG 0.4533 TRUB1-[KIAA0534]-GFRA1
805214 rs3814218 10 NC_000010.5 105253204 G A TTGGACGATTGCTTGGGTGAGCCACGATACATACGTTGGTGCATTCATTTA 0.8981 SH3MD1-[ ]-FLJ22559
806436 rs11010228 10 NC_000010.5 35856021 C T TCCATCAGGCCCATTCTTGGCATCACGTTAGTTTTCTGATAATTTATCACA 0.6246 CREM-[C10orf9] CX40.1
811022 rs7069805 10 NC_000010.5 21062602 T C TGCCTTCCCAGAAGCCAAAGGATAATGATGGTCTCATTCTTCACATTGTAA 0.7095 LOC220998-[ ] NEBL
813112 rs3865353 17 NC_000017.6 5561640 G T TATTAACAGAACAAATGTGCAGAGGGATACACAGACAGGATAAAATCTAAA 0.5718 C1QBP, MGC4189, NUP88
[DHX33]F-LANa, MIS12, LOC388326
814339 rs17747162 17 NC_000017.6 10080545 A G GCATTCACTCTCTCCCCTTTAATCTAGGTTCCCTGAGGCTACTGGAGGCCT 0.6573 RCV1-[GAS7]-RPS27AP1
814347 rs3826528 17 NC_000017.6 10086172 A G AGTTGCCAACCAGGTATTTCTCCCCAAATGTCCACTGTTACCTGAAACTCC 0.6873 RCV1-[GAS7]-RPS27AP1
814713 rs12150523 17 NC_000017.6 11045062 T A GAGGTTTCATTACCAGTAACACTGCTGACGCTTGAGCTCAGAGGTAGCAAG 0.721 LOC400573-[ ]-LOC388336
821871 rs11869222 17 NC_000017.6 49468518 T C ATCTCATCTGCTCCCACAACCACCATCTAAAATAGGCAGAGCAGGTTTTAC 0.8306 LOC400604 [ ] SPAG9
829556 rs3822787 5 NC_000005.5 9345951 A G TTTCATATCCCACACTGAATACCTTGTGATGGCACTGCCACTACCACTGTT 0.8257 MTRR-[SEMA5A]-TAS2R1
829565 rs6874451 5 NC_000005.5 9339456 C A CCCTTCAAGAGCTGACTGACCAGGGCTGGACAGTTAACTCACTCCTCCAGT 0.2043 MTRR-[SEMA5A]-TAS2R1
842261 rs16887892 5 NC_000005.5 57453557 C T GATGAGCCCTGCTCCCTGGGTAAGGCCGGTGTGGATGAAGAAGTGGTCAGA 0.8404 LOC401188-[ ]-PLK2
848514 rs12350573 9 NC_000009.6 117713981 T C GGTCCTGATATACTATGATAAGTGCTATATGCAGAGTGAACACAGGGCACT 0.4887 DBC1-[ ]-CDK5RAP2
849011 rs10984496 9 NC_000009.6 117483406 C T CCTAATCTCTGGGAACAAGTGAAATCGAGAGAGCCGGAAGCACCCAAAACC 0.8859 LOC347165-[DBC1]-CDK5RAP2
863475 rs6476875 9 NC_000009.6 4519671 T C ATTAGATAATTAAAAGCCTCTGCCATCAGTCAAAATGAAACTTTTTTTGTG 0.6466 ZNF515-[SLC1A1]-C9orf68
872816 rs7855014 9 NC_000009.6 75386914 C A GATAATTGATAGATTGGTTGAGTAACTAGAAATAATCAGTGCAATTAAATT 0.5079 C9orf65-[VPS13A]-GNA14
872845 rs10781429 9 NC_000009.6 75346051 A C TCTTCTGTAGTCATATAAGAAATTTAAGGCAATAGCAGATATTTGTATATT 0.4739 C9orf65-[VPS13A]-GNA14
882230 rs10959932 9 NC_000009.6 11552051 G A TGTGACAGTATTTAAAATGCAAAGGGAAGACTTAGAGAGTAGAGTATGTCT 0.7533 LOC340479-[ ]-TYRP1
882560 rs10125743 9 NC_000009.6 11367279 A C GCAATGTCTAACCTTGCCTTCTTTTAAGAAAACTCTGTGTCTGTGTTGCAT 0.0731 LOC340479-[ ]-TYRP1
882595 rs1029187 9 NC_000009.6 11347578 T C CTCCCATCTGTGCCTGCAATATAAGTTTGAATCACTGAACTTATCTGATTG 0.9284 LOC340479-[ ]-TYRP1
883568 rs7967032 12 NC_000012.6 1916360 T G AGCCTGCGTGCTGCAAACGACGCATTTGACCTCCAAGATGACTCCACGTTC 0.493 LOC399984, CACNA2D4 [ ] DCP1B
885372 rs4765746 12 NC_000012.6 3600144 A G TCCAATCAAGTCTCTGCTACTTAGTATCTTATTAACTGGPACCCTCTAAAA 0.3636 HRMT1L3 [ ] MGC4266
891440 rs7959121 12 NC_000012.6 125182304 C T CCCTTCAAATTCGTTAATTCTCTGACTGCAGTTGAAGAAAATCCAGCCAAG 0.9911 LOC387894-[ ]-LOC144678
894518 rs11063482 12 NC_000012.6 5029947 T C TCTGCCTATGACTCTGGCCAGTGTGTTTTTCGCTGAGCTGTTGGTGGAAGT 0.7316 LOC390282, KCNA5 [ ]-LOC387826
897732 rs2110099 12 NC_000012.6 10921228 C A TTTTCTAGTTGATTAGGCAGATTAACTTTCTGTTTTTCTGCTGACATAAAT 0.3716 PROL4 [ ] PRH1, TAS2R13, PRH2
898321 rs2889626 12 NC_000012.6 8131284 A G AGGCTGAGGGAATCTGCTGCCATGAATATCCATTTACTTACAGAATTTGTT 0.4393 C3AR1, FHX [DKFZPS66B183]
CLECSF6
903569 rs3764022 12 NC_000012.6 9724791 C G TTTTCAATAATTTTTTCCAGGTTGTCTGCATTCAAAAGAGCATTCTATTAA 0.6714 LOC374443 [LLT1] LOC400000,
DCAL1
904811 rs12424340 12 NC_000012.6 96108690 A G CCTCTTTTTCAAGATGAAATATGCAAAGTGAAGTATGCAGATAGCAGGACC 0.7507 NEDD1-[ ]-NCRMS
906272 rs7304507 12 NC_000012.6 16545580 G A CACAACTGTATCTGAACAGATTCTCGTTACATAAAACCGCACACACAGTGT 0.2683 LOC400011-[ ] DAT1, LOC121520
908741 rs10492234 12 NC_000012.6 4457860 T G ATAATGGCACCAATTATTTCTTCAATTATGAAGGCACCAATGGGATGGAAA 0.9472 FGF6 [ ] C12orf4
910353 rs7968801 12 NC_000012.6 12928074 A G CTTCAAACTTGTGCAAGATGGTGCCATAGAGGATAAAAACAAGATGGAGGC 0.3915 LOC387841, LOC341465 [ ] RAI3
918677 rs16932246 12 NC_000012.6 27675896 G A TACCTTCATATAATAGCATTTGAAAGGCTCATTAAATAGAACAGAGAAGAA 0.7807 LOC341346-[PPFIBP1]-LOC387849
918719 rs7959164 12 NC_000012.6 27691713 T C ATTGTACATTCCTAATCTACACGAATTTTCTCCAAATTGTATAGGCCTCCT 0.24 LOC341346-[PPFIBP1] LOC387849
920234 rs1029398 13 NC_000013.6 30597288 A G GTTTGACTCATTTCGGGAATATTCTATCTCCACCATTTTTCATTGCCCTTT 0.7692 LOC196549-[13CDNA73]-BRCA2
921310 rs2858826 13 NC_000013.6 31504291 A G GAACATTCAAGTTTAAAGTGAAAGCGAGTACAAAGCCAAGGTACAGAAAAG 0.4179 LOC387918 [STARD13]-RFC3
944388 rs9558696 13 NC_000013.6 104519581 C T AATTTTAAGCCAAAATTGTTTTTCACAATTGCAACCATAATTCAGTTTTTC 0.9159 LOC144920-[ ]-LOC341604
945100 rs9783551 13 NC_000013.6 96167159 T C CATGAAGGCCAACAAGAAATAGAGATGTTGAAAGAAAACAGAGAGAAAGGA 0.4442 LOC387943-[ ]-KPNB3
962652 rs9931136 16 NC_000016.5 25504539 G A GTGGTCAGGTTCTGGACAGTTCTCTGTGAGAATATTTAAATGATACATTGC 0.5767 HCP39-[ ]-HS3ST4
972242 rs39573 16 NC_000016.5 8401150 A T CACTGATGAGTACCAGACTAGAAGAAGATATTTGGAATACCACAGAAGGAG 0.7096 A2BP1-[ ]-LOC401830
979327 rs6668830 1 NC_000001.5 4892273 C G TGCCCTCTGCACCTTGGGCACAAATCGAGATTGGATTCCTGGGGAAACTCT 0.7515 LOC388589-[ ]-LOC126772
982183 rs7522080 1 NC_000001.5 4145831 T C TGCAGGTACACGGAGCGCCTTCTTTTCGTTTAGAGCATTGGTAAGTACCTA 0.9751 LOC401937-[LOC284661]-SHREW1
1001406 rs6693871 1 NC_000001.5 27391611 C T TCTGTTGGCGAAAGAAAAAATGCACCTGTATTATGTAAATAAGAATCCATG 0.1008 WASF2 [ ]- DJ159A19.3
1004017 rs4265476 1 NC_000001.5 30531562 A G TTGCAAAAGCCTAAGGACTGTGTAAATATTCATAATACTGTTTTTAAATTA 0.007 LOC388615-[ ]-MATN1
1009275 rs12078977 1 NC_000001.5 34814977 T C TGGGGAAGGGTATGTTTGCAGGCTATTGTTAACCCAGATGAGTGAGATGCA 0.9556 SAPAP3 [LOC388617]-MGC14276
1016164 rs17362424 1 NC_000001.5 41207697 G T TTGTAAGAAAGTGTGTGCTATTTCTGGGTTATCCATGTGGGCAGGGGGAAA 0.7777 SCMH1-[ ]-LOC391030
1043573 rs1496012 1 NC_000001.5 64177746 G A GTTGAGTCCCATTATCACTCCAGGAGGTACTTTTGGGATAGGTCCTTTTTT 0.5974 MGC35130-[ ]-KIAA1573
1046450 rs17486706 1 NC_000001.5 66377596 A G TCGTGCAATGTCTCTGTGTGGTAGAAAGAATAAGTACGGTAATCCTCCCTT 0.8692 PDE4B-[DKFZp761D221]-FLJ40873
1054104 rs11162856 1 NC_000001.5 75120079 T C GTGCCTTTTTCATACCTTAAATAGATGCTCATAAACCAAAGTGTTATATGT 0.7249 LOC148864 [MGC34032]-LOC388641
1054144 rs666397 1 NC_000001.5 75132657 1 C CAGTATAATTTAAGATTAATATTGCTTGTGTAGTCAATGCATATTCAGGGT 0.2729 LOC148864-[MGC34032]-LOC388641
1057517 rs626492 15 NC_000015.5 46559654 T C GATTTGTTCTAAGTTATCTCTACTCCCTTGCCTGGCCTTTTGTTAAAAACA 0.2488 DUT-[FBN1]-LOC400370
1059228 rs1933328 1 NC_000001.5 80781549 C A CCACCAGTCCATAGGGGTGAAAAAACCTATTTTTATGCACTGTGACATTTT 0.3202 COX6A1P-[ ]-LOC391050
1059350 rs1195772 1 NC_000001.5 80957737 A G GGCCAACATCAGAGTTTTTCTAGCCGAAGTTATTTTAGAGGGTAATCAGGA 0.8526 COX6A1P-[ ] LOC391050
1062376 rs12133778 1 NC_000001.5 83790219 A G AGAAAACAATGTTACAGTGCAGTTGATGGGCCCTTCATGGTGCTGGCCACT 0.4847 LPHN2-[FLJ23033]-PRKACB
1064263 rs12725350 1 NC_000001.5 85766024 A G CATTCATTCTTTTATTCTTTAATGCACTCATTCATTCAACATTTATTAAGC 0.7568 FLJ20729-[COL24A1]-K1AA1229
1064904 rs7543542 1 NC_000001.5 86957632 A G TCTAAGTGCACTGCAAATGTGGCATAACTAGTTAACTTTCTTCAGTGATTT 0.1962 SEP15-[HS2ST1]-LOC339524
1066286 rs551904 1 NC_000001.5 89148422 C G ACCTATTTCCTATAAGACCATGGAGGTGAGCTTACCTCTCTAAGCCTCAAT 0.6953 GBP4, LOC388646 [ ] GBP5
1067713 rs17131120 1 NC_000001.5 90580175 A G CAATCATGTTACAAAAAGAAAATTAACAATACCCTAAAATAAAGAATTCCA 0.9274 FLJ20403-[ ]-BARHL2
1067961 rs17131433 1 NC_000001.5 91348930 C T TAGATGTATTAGAACATCATCCTTCCGCTAGTAAATAGAGTACTGTGGGTT 0.7929 LOC164045 [ ]-CDC7
1068351 rs10493858 1 NC_000001.5 91759738 C G AACTTCATTTTCCAGCCTCACCAATCTTTTAGAACAGAAGATCAAGTCAAA 0.7742 TRAP2-[TGFBR3]-BRDT
1071700 rs11165895 1 NC_000001.5 97498176 C A AAGTAGAACCATITTGAGTTTTTCACAAGAAAGATATTTAAGGCTGACGTT 0.1506 PTBP2-[DPYD]-LOC400765
1071708 rs6663357 1 NC_000001.5 97507862 A C TATACTGAGTGAATGGCTATTAAACATCCATCCCAATGTAAGTAACAGGAC 0.1436 PTBP2-[DPYD]-LOC400765
1084766 rs17563390 1 NC_000001.5 108741590 G A TATCAGAAATGCTTGACTTAGAAGCGTCTCCTTCATTTGCTGGAATATGAA 0.8716 STXBP3 [MGC26989] GPSM2
1085178 rs2297757 1 NC_000001.5 109013646 A G GTTACAAGTTATTTCTTTGGTGTCAACGCTCATTTTGTGTGTGTGACTAAC 0.6066 LOC127003-[KIAA1324] SARS
1085506 rs682288 1 NC_000001.5 109022367 C T TGGTACAGGTAACACTCATAAGTCACGTGTATAGTACTCTCCAATTGACAA 0.3918 LOC127003-[KIAA1324] SARS
1088326 rs4838884 1 NC_000001.5 110827297 G A GAGCAGACCTGATGACACTGAACCTGGCTAGAGAGGTACTCAAAACCAAGT 0.19 RIF1 [ ]-MGC54289
1095559 rs17185373 1 NC_000001.5 117629056 A G GTGTCAATGCATAATTTTGTAAACTATGTTACTGTCCTCAAGATTACAAAC 0.5434 LOC401959-[ ]-GDAP2
1096046 rs6671887 1 NC_000001.5 118213764 A G ACTAGAGCCTTTATTCTCAGAATCTAAGTTATTGTAGGTAAAAAATGGATG 0.2368 WDR3-[ ]-LOC391072
1097038 rs12030458 1 NC_000001.5 119199457 A C AGGGAATGGTTAGTGGCACTTAAAGAGACTGAAATACAACATATGGGGAGT 0.924 LOC343495-[ ]-HAO2
1102760 rs4950328 1 NC_000001.5 144511888 T C TGAAGCCTCAAACTCCTTGCGTGTTTAATTTACTGCTGTTCATCCAGAACT 0.2817 CHD1L-[ ] BCL9
1110134 rs564211 1 NC_000001.5 150330659 G T ATTTATCCATAACTGGTATGACAGGGAATCTCAAAAAAGGAAATATCCTGT 0.8768 SPRR2C [ ]-LOC149018
1119230 rs1875766 1 NC_000001.5 157767072 G A TGCAGAGGCAGGCTTAGGTGGAGTTGAGCTAGATGTAACAGGACTATTTCT 0.103 CD84 [ ] SLAMF1
1124752 rs12034856 1 NC_000001.5 160731951 A G ATTACGGATAGAACAGGGGAGCCTAAGTTTATTCTCTCTGACCTCCCACCT 0.5336 COCA1-[ ]-LOC388711
1125283 rs11577916 1 NC_000001.5 161037481 A C GCAGGAGAGAATATTTAGTCTGGCCAGATCAGAGAGGGCGAGGTGGAGAAT 0.7547 CDCA1-[ ]-LOC388711
1128559 rs4578194 1 NC_000001.5 162837993 C T TGACATTGAAGACCAGAATGGTTCACTTGATGAGAGTCCCCAAAGCTAGTG 0.673 MGST3, LOC400795 [ALDH9A1]
LOC54499
1132867 [NULL] 1 NC_000001.5 169327931 C T TCAATCTTTTCACCTTTACGTTTGACCTTTCAATCCTTTCGCCTTATTGAG 0.7652 LOC127099-[KIAA0820]-LOC92346
1136710 rs1498123 1 NC_000001.5 176921360 T G TAAAATTTATAAGGTGATTTTTGTTTCTACCAGTGTAAAGAAGACCCATGG 0.6995 TDRDS [ ] MGC16664
1136732 rs2454196 1 NC_000001.5 176955962 G C TTTGGGGTGGGTGATGGGACAGGCTGTTGAATAGCAGAAACAATGGAAGAA 0.4391 TDRDS-[MGC16664]-LOC163590
1139305 rs7534913 1 NC_000001.5 178777653 G A GTGAAGCTTCCTTCCCTGACCTTTCGCTTATCATAATTGAGACCTATTTAA 0.4891 LOC284646-[CACNA1E]-LOC127665
1139328 rs10494540 1 NC_000001.5 178788928 T G TTCAGGAGACTGGGAAACATTGGATTGAACACATGATATGTGAGCTGGGAG 0.4931 LOC284646-[CACNA1E]-LOC127665
1142006 rs17574056 1 NC_000001.5 181421075 C T AGATGTTATCCAGTTTGCCAAGAAACCCTCACCTAGAGGCACCAAATTATT 0.5719 C1orf19-[ ]-LOC391144
1148525 rs1535868 1 NC_000001.5 190721875 G A AAGATATGTCCTGTTCAAAACCAATGTTCTGAGAGTTTGAGAGCCGTGAAA 0.7708 HRPT2-[ ]-LOC401978
1150093 rs1929218 1 NC_000001.5 192025798 T C TTATAAATTACTACTAGTGTTAATATTTCCTGGAACAGTAAAAAGAAGTAG 0.3091 LOC401978-[ ]-SLICK
1162438 rs7551756 1 NC_000001.5 201263042 A G ATAGATGAACAAGTAAAAAGTCTCAATGGGGTCTGTTTCACTGTGGAGCAG 0.643 FLJ40343-[S0X13] REN,
FLJ10761
1166312 rs2036100 1 NC_000001.5 203085841 C G TCTCCCACTCTTTTCCCTTCTCCTTCTTGCCTATGAAGCCTTTCCTGACCA 0.6087 LOC284581 [SLC26A9]-LOC391156
1178707 rs2147477 1 NC_000001.5 213328552 A G GCAAAGAAGAAAAACTAATAAGCCCATAACTGACATTGAGTTCTAGTTGAG 0.3312 LOC391164, LOC200125 [ ]-USH2A
1203600 rs271735 1 NC_000001.5 231746617 A C AGCTCACTCCCTGCTTCAGAAGTGACCATGGATCTCAATGGCACAAGATTT 0.3847 TARBP1 [ ]-IRF2BP2
1203638 rs271771 1 NC_000001.5 231761537 C G AGGATAATAAGGCTGACCTTGCCGGGTGTTGGGAGAATCAGATAATCAGAG 0.3927 TARBP1-[ ]-IRF2BP2
1205110 rs4659838 1 NC_000001.5 232606464 T C TACAGAACATCTGAATAGTGGAATGTTGAGCCACCATTAAATAAATTTCTT 0.3449 GGPS1-[TBCE] MGC39558
1205283 rs6429197 1 NC_000001.5 232816166 G C AAATTTGGGCAAATTACCAACCATTGTGGGTCTCAGTTTCGACTGTTAACA 0.7073 MGC39558-[GNG4] CHS1
1206778 rs35712364 1 NC_000001.5 233804984 T C AAACAGTACCATACATTGCCTTTTATTAGATTTTTTTTTTTTTCCAGAGTC 0.9569 LGALS8-[FLJ10359]-ACTN2
1208382 rs2808221 1 NC_000001.5 234529712 T A GGCAGACAGTGATCTCCAGGATATATCAGTAAATTTAAAAATGGTAATTTA 0.6403 LOC388754-[RYR2]-ZP4
1208424 rs7545575 1 NC_000001.5 234565210 A G TATGTGTATAATTGCTCATTCATGGACTGGTGGACAAGCCTCTTTCAGATG 0.6917 LOC388754-[RYR2]-ZP4
1215253 rs17713396 2 NC_000002.6 217201 C T GGAATGCATGTGCTGGTGAATGTTACGGTGGGGAAATGGTTGATGAGACTC 0.6475 LOC400937 [SH3YL1] ACP1
1219347 rs2580871 2 NC_000002.6 4501226 A G GCTAATGTGAATTCAACACAGGAAAACTAAAAGGTGGTCACTGGTTTTCAT 0.1308 LOC253662-[ ]-LOC200475
1221183 rs1554740 2 NC_000002.6 6251182 T C AAAGTAGAAAACAGCAGAGCTAAAATACAAAAATTTTCAAAGAAATAATCT 0.6613 LOC400940-[ ]-LOC391349
1224387 rs4233868 2 NC_000002.6 9523902 A G GTGTATTTAGAATTATGTCTGACACACCGTTAAGAACCATAAAGTATTAGT 0.7102 LOC129642-[DDEF2] ITGB1BP1
1226296 rs13016049 2 NC_000002.6 12121165 G A CAGTAAAGGGAGAGGAAGAGGATTTGAGAAGCCTAGGGACTTAACATGCTT 0.5979 LPIN1-[ ]-FAM10A3
1228577 rs1349842 2 NC_000002.6 13985779 A G TTGTTTGCCATTCCATTTTGAAACAAGTAGTATAATTCTAAAACAAACAAA 0.9133 TRB2-[ ]-NSE1
1232320 rs1983376 2 NC_000002.6 17410547 A C GATCTACAATTCTGGACTTGGCAGCAACTTCCCAGTAGCCATTCTACAATG 0.8243 DKFZP566A1524-[LOC391354]-
LOC388925
1234410 rs4832602 2 NC_000002.6 18697968 G A GGCTTGGAGAATCTTTGCATGTACAGTTTATATAAGCAAGCTTCATAATTA 0.3249 KCNS3-[ ] RDH14, NT5C1B
1246865 rs12623550 2 NC_000002.6 34574064 G A TTAAATGTGAATTGTAACTTTATACGTGCGCTATTTTTAACGTTTCTCTCT 0.8355 LOC344371-[ ]-MRPL50P1
1255229 rs11124986 2 NC_000002.6 44483370 G A AGAAATAGAAATAAGGTTTCCAGTTGTTATTTACTCAGGCTTCCAATTATT 0.3088 PPM1B, LOC391371 [SLC3A1]-
FLJ23451
1256280 rs11693792 2 NC_000002.6 45235692 C G ATAGTACAGAATATGGCTAAPAGGACCAGGTGTGAGGTGCAGATTAAGTGC 0.8445 LOC151111, SIX2 [ ]-LOC400952
1257281 rs13001566 2 NC_000002.6 46804021 T G TACAGTTCACAAGCTCAAAGCTTTGTTGTTCTCTGTCGTCACATGACTATC 0.4778 ARHQ [PIGF] CRIPT
1260720 rs10495984 2 NC_000002.6 50054137 C G AGTCAGATCCTGCAAAATGATTTATCTGTTCCTATGCCITTGGCCTCTAGT 0.6132 LOC339793-[ ] LOC130728
1266440 rs777593 2 NC_000002.6 61393637 C A GAAAGATTTCTACTGTAGAGAACAACGTGGCATTTCTTCAGGGGATGGAGA 0.3749 AHSA2, LOC339803, LOC339804
[USP34]-XPO1
1266507 rs10496092 2 NC_000002.6 61499213 C T GGCAATTAAACAAAAATTTAAAGTACCACCCTGAGAGGTAAAAAGAGTAAA 0.6278 AHSA2-[USP34]-XPO1
1266518 rs1838978 2 NC_000002.6 61515457 T C GTTTCAAATCATGGAAGCATGTTATTTATAAGGAATGTATAAAATATCTTT 0.6219 AHSA2-[USP34]-XPO1
1266537 rs2694632 2 NC_000002.6 61533216 T C GTGAAAAGATATAAAGCAATGTTCCTTCATTTTTATGAATTTAAAGTACCT 0.6313 AHSA2-[USP34]-XPO1
1266544 rs2463102 2 NC_000002.6 61545829 G C CCGACATCTGCTTATTAACAATATGGAATGTTGAGAGCTTTACGAAACTGA 0.6375 AHSA2-[USP34]-XPO1
1266553 rs778143 2 NC_000002.6 61556424 C A TTGGGTTGGGCAACATGTGGAGGAACTGAAAGCCTGGAGCCTGGGCCCAGG 0.633 AHSA2-[USP34]-XPO1
1268020 rs11885480 2 NC_000002.6 65310704 T C ACCTCCCCTTATCAAAGACACACACTTGAATAGCGTGATCAGTGACACGTT 0.181 KIAA0582 [RAB1A]-LOC150984
1268046 rs11684110 2 NC_000002.6 65342824 A G TGACCTGTTTCAGAGCACACCTCCAACCTTACCCAGCTCTCACCCACCTAC 0.3055 RAB1A [ ]-LOC150984
1273590 rs13384240 2 NC_000002.6 75074409 T C GGAAGAAAGATACTTGGAGAGTTAATGATGTAAGGACACAAGTACAGTCAT 0.8218 SEMA4F-[HK2]-POLE4
1276506 rs10170918 2 NC_000002.6 80241437 A G TTCCTATGCATTATGATTTGAACTCAAAAAACAGAAGGCTATCAGAAAGAC 0.7298 PAP-[CTNNA2]-LRRTM1
1276558 rs1867806 2 NC_000002.6 80293514 T A GAAGGACTGGACAAGACAGGAGCATTTCCTAATCAATTTATGCAAAACCTC 0.6288 PAP-[CTNNA2]-LRRTM1
1276573 rs1900265 2 NC_000002.6 80317959 T C TGTGTTTAGAATATGGACTGTGTTCTGGCTGTTACAGGTTCATGTGTGTTA 0.6234 PAP-[CTNNA2]-LRRTM1
1276632 rs4852559 2 NC_000002.6 80376037 G A TGTATACTCTTGTGTTATGATACCCGCAGCACAGCAGTGCCAGGCACTCAC 0.502 PAP-[CTNNA2]-LRRTM1
1276639 rs4142758 2 NC_000002.6 80389782 G A GCTGCTCTTTGAAGACAATATTTTCGAATTTCATCTGTTATTTCAAGGTTT 0.502 PAP-[CTNNA2]-LRRTM1
1276648 rs7589687 2 NC_000002.6 80402602 A T CATGATACCTGAGGAAGTAACAAAGATTATACAATCATCCCTAAGTATTCA 0.4956 PAP-[CTNNA2]-LRRTM1
1276683 rs2587148 2 NC_000002.6 80438390 G A GAACTTGCTTTTATTTATCTGTCAAGGAGCCTTATGTCTGTGAAATCACTA 0.3232 PAP-[CTNNA2]-LRRTM1
1276697 rs188836 2 NC_000002.6 80454928 G A CATTGTCTCTTCTTGAGAAGAATCAGTTTGCACTATATGATATCTAAGTAC 0.3908 PAP-[CTNNA2] LRRTM1
1276713 rs318366 2 NC_000002.6 80464250 G A GTGCCCTGCAGGGTTGCTTAGGCCTGTAATGTGGTCCTTCACACCTCTCTC 0.3745 PAP-[CTNNA2] LRRTM1
1293364 rs2630505 2 NC_000002.6 108260966 C T TTTCTTTGCAAACCTGTCTTGCCTATTTTTCCTTAGGTTGAAAGGATTCTG 0.1429 SLC5A7 [ ]-LOC391418
1311548 rs167164 2 NC_000002.6 123660072 T C TGATGATTTCTGAGAAGATATGACTTGTAACTTTCCAATAACACTTTTCTA 0.1742 LOC389028-[ ]-caspr5
1325111 rs4560177 2 NC_000002.6 133419267 T C GCCTGAGTTTTCCTTAGCAACCTAATTCTGTTTGCCTTATGTGCTTGACTT 0.1329 LOC401012-[GPR39]-MGC29643
1327662 rs7803969 7 NC_000007.8 95114075 C G TGCAGGGAAAGAAGGCCAAGAATGGCCAACACTGACTTGGAGAAGGATACC 0.8493 LOC389533-[DNCI1]-SLC25A13
1329983 rs12470730 2 NC_000002.6 135900830 C T ATATTGAATACTGATATTTTGGGGCCGTTATTAACCCAGCTTTCTTTTAAA 0.7975 ACMSD [CCNT2] FLJ23074
1334452 rs16840302 2 NC_000002.6 139064740 T C ACAGACTGGTAACATCTTCCCATTATTGCATGAGAAATTTTTTTCCCTTAG 0.8954 HNMT-[ ]-LOC150498
1337252 rs7563559 2 NC_000002.6 140992751 T A TATCCTCCAAAACACCTCCATGGGATCTTTAGAGAACTTCAGAACATGGTT 0.5725 MRPS18BP2-[ ]-LRP1B
1356550 rs10497140 2 NC_000002.6 155700080 C T GGGAAAGGCCATTTCAGCTCATTGACAGGTAGTAGAGGATTAACGTAATTG 0.9374 GALNT13-[ ]-KCNJ3
1363739 rs1834216 2 NC_000002.6 163941427 C T GGGTGACAAAGAGTATCTTGAGCTCCCTGAACTGTAGATCACAAGCCCCTT 0.4037 KCNH7 [ ]-FIGN
1369909 rs17568204 2 NC_000002.6 168739502 A G GAGAACTTTGTATGCACTCACAAGTATACATCAAAATCTCCTGGTGGTTTG 0.7759 CMYA3-[ ] LOC401018
1385352 rs1518408 2 NC_000002.6 181160044 T C CATAGTGAGACCCTGGAACCCCTACTAAGCTGTTTGATTTAGAGACTCTTG 0.0602 KIAA1604-[ ]-UBE2E3
1386738 rs6755680 2 NC_000002.6 182431790 C T TATAGTGATTAAAGTAGCACTTACACTTTTGACCCTGGCAGGTATTATCTG 0.7009 UBE2E3-[ ]-ITGA4
1387272 rs12621807 2 NC_000002.6 183058617 T G GCAGCATAATGTCCCATCAGTCCCTTTCTGACAAATAACCTAGAACTCTCA 0.7842 LOC344318 [LOC151242]-PDE1A
1390626 rs2170203 2 NC_000002.6 185811547 T C AAACCAACACATTGCAATTATTTTGTATTATATACAGTATAAGTACATCAT 0.3647 PRO2964-[LOC91752]-LOC389066
1401365 rs34481285 2 NC_000002.6 197542278 G A TTACAGACGCTTAACACAGTTTAACGAATTTCTCTGATACACCAACAGTGG 0.9059 STK17B-[NEDL2]-FLJ39660
1405790 rs4393736 2 NC_000002.6 201334094 A C ATCACTTGGGTAATGCAACCCATTTATCTGCTCCCACTGTATAACAGCGGA 0.8052 FLJ22555-[ ] DNAPTP6
1405831 rs17592517 2 NC_000002.6 201359478 A G TATTAATCTTTAAAAATTTTAAAGTAAAGCCTCTACCTATTCACAGCAAGA 0.8298 FLJ22555-[ ] DNAPTP6
1406391 rs6745304 2 NC_000002.6 201692033 A G AGACTCATCTCCATGAAATGATAGGATGTTCTCTTGTGTGCATTCCATTGG 0.3409 TRIPIN [AOX1]-AOX2
1410980 rs12694177 2 NC_000002.6 210391688 G A AAGGAGATCAGGATAGCCAATTTCAGGAGCTTCCCTTCCTTGATCTCATTG 0.3397 LOC402116-[ ]-MAP2
1431533 rs4487084 2 NC_000002.6 228915718 G A AACAGGCTAAGGTAAATACTCACGCGAAAGAACCAAAAACTTTGTAAGAGT 0.2197 CCL20 [ ] FLJ25955
1442327 rs946630 14 NC_000014.4 32431904 G A CTTTGGGGAACTGAAAGAAGCCCTGGAGAACACAATATACAATGGCACACC 0.1732 EGLN3 [ ]-C14orf147
1443605 rs8003136 14 NC_000014.4 33665950 G A CCCACCACCACTATTTATTGACTGGGTGACTATAGGTAAGATAGTGAGCCT 0.309 CDC10P [KIAA0391] MRP63P8
1443883 rs10145821 14 NC_000014.4 34362385 T C TCTTTGAAAGCCTTGAAAATCCTAATGTTCTTGCTAACAGTGGAAATGCTT 0.997 BRMS1L [ ] LOC390468
1445906 rs1112504 14 NC_000014.4 39699749 T G AGACTGATACATTGCTCATATTCATGTTGATCTTCATTATGTTTGTGACAC 0.2219 FBXO33-[ ]-LRFN5
1447578 rs7142438 14 NC_000014.4 41754122 C G TACACAAAGACAAATGAGAAATATTCTTACCTCAGGAGGTTAATATGAAGT 0.7503 TUBBP3 [ ] HNRPUP
1456212 rs880193 14 NC_000014.4 54281613 G C CTTGAAAATTGTTATCTCTTGTTTAGTATCTTATTTCGGAAAGCAGCATCT 0.1567 LOC387989-[ ]-PELI2
1468451 rs17261246 14 NC_000014.4 90069805 T C TAAATGGAATGAGCACGTCTAAAAGTGTATATACCATGTGTCCTAATTTCA 0.966 KIAA2010-[C14orf161]-MTAC2D1
1476779 rs6916070 6 NC_000006.6 12179270 T C AGTAGGTCCTGACTTCATCAGTCTATAGTGTTCTGTTCCAGCATTCTTTTG 0.7347 LOC389369-[HIVEP1]-EDN1
1487452 rs6901756 6 NC_000006.6 41872445 T C CATGCATACTTACATAGTTCATCAGTAAGTGAGGATTCAATGGATGGATGA 0.8661 C6orf49-[MGC20741] USP49
1506595 rs480295 6 NC_000006.6 81229472 G A ATAGGAGGACTATTCAGTATTTGGTAGGGAGCAGGGTAACAGAAAGGTTAC 0.3183 LOC340171-[ ]-C6orf37
1507256 rs16894046 6 NC_000006.6 83002753 A G GATTTTTGCACAAAATGGGTTCTTCAATATAAACCCTTCAGTATTTCCAGC 0.987 IBTK [ ]-TPBG
1507420 rs2983879 6 NC_000006.6 83149474 T C CTTTTAACTCTTCCTTTACTGCATTTGTGCCTTTCCAATGACAATCTCGTT 0.3868 TPBG-[ ]-C6orf157
1508781 rs9359604 6 NC_000006.6 85362249 G A CTGAACCATAAGCACTGAATTGACCGTTCTCTTTCCCCATAACTGCCATCT 0.8774 C6orf84-[ ]-LOC401269
1525920 rs6937080 6 NC_000006.6 121796228 T A GGAGATGATACCTTCATCGAAGACATCCTCCTATTAGCATTCTAGAGCAGA 0.8254 GJA1, LOC260339 [ ]-HSF2
1527003 rs17686735 6 NC_000006.6 123692693 C G TACACTAACACAGAGTGCACATACCCCATCTTTTAAGCCGAGTTCCATTAC 0.5841 C6orf213-[TRDN]-TCBA1
1529845 rs17056873 6 NC_000006.6 129456505 C G TTGAAAGCTTCTGTAAACAGTTGAACTTCAAATTAAAAGGTAAGTAGGAAC 0.9897 LOC338470-[LAMA2]-ARHGAP18
1529998 rs265326 6 NC_000006.6 129570746 C G GTTTATTTTTCATGGTTTTAACCCAGCATTAAGTAGCATGGTTTTTAGCAT 0.8492 LOC338470-[LAMA2]-ARHGAP18
1530007 rs265392 6 NC_000006.6 129576597 A T AATATGAAAGAGACATGTGAATCTCTGCCTTTGAATACTTAGGATGTGTTT 0.8412 LOC338470-[LAMA2]-ARHGAP18
1532522 rs6924201 6 NC_000006.6 132877599 C T GTTCCATAACCTTTGGGGCCAATTACAGGTCATGGATACACTGTTCCTAAG 0.8415 TAR3, GPR102, TA4 [ ] PNR,
GPR57, GPR58
1534840 rs10499200 6 NC_000006.6 138752522 A G AACACCAGCATGGATGACTTCCACAATGATATGACTTTCATGCCTCCCAGT 0.8369 HEBP2 [ ]-LOC401275
1534880 rs7765940 6 NC_000006.6 138775313 C T AAGAATTATTAAAGTACCTACTACACACTACATACCATATATCAATTAAAT 0.8395 HEBP2-[ ]-LOC401275
1538591 rs485434 6 NC_000006.6 147492291 G A GAAAGAAGTTTCACCTGCATGCTGCGAGCTTTGTGCCTGCTGCTATAATAA 0.5208 LOC389431-[ ] STXBP5
1542474 rs11156106 6 NC_000006.6 156742533 G A TATGATTGTAAAGAACATTACAGCTGAAAACTCAAAATAATAAGTGTTTTG 0.4102 NOX3-[ ]-LOC389437
1542978 rs6909234 6 NC_000006.6 156384857 C T CTTTGAGAGCACAAAGAGGTGGCAACTAACATACTCCAGTGTGGGACAGAG 0.5256 NOX3-[ ]-LOC389437
1552540 rs6947755 7 NC_000007.8 15983390 G C CAAAAACCTTAATTTAAAAAAATCTGTATCAAAGAATAAAATTTTCCCAAT 0.7081 MEOX2-[LOC402250]-SOSTDC1
1553131 rs1404963 7 NC_000007.8 16906648 A G ACTGTGGTGGCAAACTCATCTATTTATTTAACACTGGTATTTCAGCCATCT 0.7549 BCMP11-[ ]-AHR
1555949 rs17152880 7 NC_000007.8 25666356 T C GCATGTGTGGAGCTTGAGCCGGCGATAAATTGAGGCGCTAATCCTGATGCA 0.9615 UBA52P1-[ ]-NFE2L3
1572691 rs17762851 7 NC_000007.8 69630695 C T CAAGTAATTGAATCTTCTAATGGAACAAACTGGTCTCTGCTTAATGATTTG 0.9142 FLJ13195-[AUTS2]-WBSCR17
1579845 rs6967782 7 NC_000007.8 96444809 T C TATCCAGATCTCTCCCCAGGCTACATCTCTCTCATGAGCTCCATACCTCTG 0.3198 ACN9, LOC392076 [ ]-TAC1
1581736 rs6977560 7 NC_000007.8 104649224 A C TGACTCTGTGTCAGCTTGACGAGCAAGTTTTTTGGTAGTGAAACATTTGTC 0.1901 SRPK2-[ ] FLJ20485
1585729 rs2590597 7 NC_000007.8 117961356 C G CTTATCACACTTITTCATTGAGTGTCTATTTTACAAACAGGGGAGATCAAA 0.3262 ANKRD7-[ ]-KCND2
1585755 rs17318046 7 NC_000007.8 117942519 C T TCATTTCGTGCAGGTCAGAAGTATGCTGCAGTACTGATTGTGAAAGAAGTA 0.4291 ANKRD7-[ ]-KCND2
1586038 rs2402460 7 NC_000007.8 118329604 A C CAGAGGAAGCTCTCCATGTAACACAAAGTGCAGTGAGGAGTGAGAACCACA 0.4936 ANKRD7-[ ]-KCND2
1586042 rs10258702 7 NC_000007.8 118335931 A T ATTTTCCCCTCTCTCAAATGTTGTAACTCCTAGTACAGTTTCTTTAGCATC 0.4881 ANKRD7-[ ]-KCND2
1586171 rs10240560 7 NC_000007.8 118668391 C T ATTTTTGTTAGAGCCATTAATTCTACTATGCTGGACTAGTCAAGAGGGCCC 0.8276 ANKRD7-[ ]-KCND2
1586214 rs1916861 7 NC_000007.8 118927945 T G CATTTCATGACATGCATTTCAAATATTTTATACAGCTGCTTCCTTAAAGAC 0.8192 ANKRD7-[ ]-KCND2
1586226 rs17279126 7 NC_000007.8 118933389 G A GCACCAAACGAATATGTCCAATGTAGGGCGAATGTTGTCTTCTCAATTCTT 0.8113 ANKRD7-[ ]-KCND2
1586261 rs17279645 7 NC_000007.8 118961544 T C TTCACGAAGAAACTAACTTTTCAGTTGCTATAAGATTTTTGTAGAACCCAA 0.8198 ANKRD7-[ ]-KCND2
1586311 rs17280657 7 NC_000007.8 119008753 G A AACAGAGATCCTACTAGACATAGACGATTTAAAAAAAAATTTGAAAAGTCT 0.8226 ANKRD7-[ ]-KCND2
1596162 rs3852883 19 NC_000019.6 6434465 A C ATACTCATGACAGCCCGACACACTCAAGCCGTGCTGCAGACTATGAAAGAC 0.5908 FAM31CCRB3, MGC2615,
MGC34725 [ ] TUBB5, TNFSF9
1597461 rs2431792 19 NC 000019.6 8939545 A G CAATTTGGCACTGCCAAGGACTTCAGCCCATAATCCCTTCTTCCGTAGTAA 0.2792 MBD3L1-[LOC400676]-LOC125963
1609848 rs7254744 19 NC_000019.6 40702499 C G TAACCAACAAGAAAAACAAGATCAGCGCTATGAGAGAGAGTGACAGGGTGG 0.268 LOC388533, Z052F10 [ ]
UNQ698, ATP4A, NIFIE14, GAPDS
1611770 rs3843043 19 NC_000019.6 46125771 C T GCTCACAAACTCAACAATTGCTTGTCTTTTTTCCTAGGGTATAAGCCTTTG 0.2645 CYP2A7, CYP2G1 [CYP2A7P1,
CYP2B7]-CYP2B6
1613798 rs3826861 19 NC_000019.6 50748460 C T ACCTGCTGGTCCCAGTGGCAGGTAACGGCTGCTCTTATCAGCAGGGGTAAC 0.3634 VASP [OPA3, LOC401922] GPR4
1614288 rs8101491 19 NC_000019.6 52334620 G A GTCGGAGAGAAACGATGGTGGCTCAGACTAGAGTGGTGTTTGTGGAACTTG 0.4561 C19orf7 [SAE1]-BBC3
1614290 rs12611429 19 NC_000019.6 52340669 A G CTCTACATTCCCATGCCTCAGTGACATTTTATTTATTTTATTTATTTATTT 0.8264 C19orf7 [SAE1]-BBC3
1614294 rs11666272 19 NC_000019.6 52350160 T C CTGGAGAGGCTTTTTTTGATTCCAATAACATGATTCCTAGGGTAAAATTAC 0.8221 C19orf7 [SAE1]-BBC3
1614316 rs3760765 19 NC_000019.6 52385001 C T GATTAATAATGTTGCTGTCCAGATTCCCGTTATAGCGCTAACCTGATGTTA 0.8132 C19orf7-[SAE1] BBC3
1614322 rs11669489 19 NC_000019.6 52391945 A T TTTCACAGTAAGGTAAATTGCTTTTATAATTATTGGATTGCCTCTCTGACT 0.8088 C19orf7-[SAE1] BBC3
1614525 rs12459087 19 NC_000019.6 52661206 G A CGATGGCCGCCATGAAACGGTCGGCGATGATGGACACTCCCAGAAACATGT 0.8824 MEIS3 [SLC8A2, NAPA, KPTN]-
ZNF541
1616405 rs2547321 19 NC_000019.6 56574475 A C TTATCCTACACATCCATATCCTGGAAGTTGAACTGTGGTGAGCTCCTGGAC 0.5439 LOC147645, ETFB, NKG7,
MGC33839 [ ] LOC147646,
LOC400712, LIM2, SIGLEC10
1618767 rs2288519 19 NC_000019.6 60401740 C T GGAGAGGCCCATGGGTACTCTTCATCTCCCAAGGAGCTCCCAAAGTCCTTT 0.5849 SYT5, TNNT1, TNNI3,
LOC352909 [PTPRH] KIAA1115,
LOC388563, MGC30208
1626238 rs209845 16 NC_000016.5 12382754 A G AGAAACTTCTCTGATCACATATCCAATTGTTAAAAAGAATTGTGGGTTACT 0.4697 FLJ12363-[LOC92017]-FLJ11151
1637827 rs2042364 16 NC_000016.5 65031268 A G GGGAAAGTGTCACACAGATTGACAAATGTGGAGTCACAAAGCAAAGGAGGT 0.4731 CDH11-[ ]-LOC283867
1645177 rs9923084 16 NC_000016.5 74134676 G T TGGCCACATTCAGGAACCAGGGAATGGAAGGGATGCTAATCTGAGGACATT 0.8546 LOC388291, PSMD7 [ ] LOC283922
1646094 rs7106188 11 NC_000011.5 3184457 A G CACAACCTTCACCCTGCTGTGCCTCGCTGCAAGGCTCTGTTCAGTCAATTA 0.5992 OSBPL5 [ ] FLJ36102, MRGE
1654367 rs9633862 11 NC_000011.5 10628447 G C GAAGAAGTCGGGTAGGCCTAGACCAGAATCCCACCTGGGTGACCTTGGGCA 0.8024 LOC399865-[MRVI1]-SH2BP1
1660150 rs2593590 11 NC_000011.5 15805635 G A TTTGTACAATCAAAAAGGAGCCTACGGGATCACTTCTGAGCAAGAGCGCTG 0.2801 LOC387756-[ ]-SOX6
1661334 rs1520886 11 NC_000011.5 18229047 C T GGGGAGTGATTTGGTCCTTTACAGACGGATGAATGAATTTCTGTATCCAAA 0.2371 SAA4 [ ] SAA1, HPS5, FAM10A5,
SM2
1667424 rs10948827 6 NC_000006.6 54430097 T G CATCTTTTTTTAAGCTTTTATCATGTTTTTTGACAATGTAGTTAAAGTCTA 0.7545 CLNS1B [ ]-LOC221344
1674227 rs2585813 11 NC_000011.5 28578799 A T GCCTTCAGCCTCCACAGAGTCTTCTAGTAGTAAACCCTTAAAGATGCTTCA 0.6198 FLJ33979-[ ]-LOC401677
1676930 rs11032833 11 NC_000011.5 34718056 T C ACTATGATTATTAAAAAGGAATTGATTGGGATTGGAAATCAAGAGGGCCAG 0.8406 EHF-[ ]-MMRP19
1678333 rs7107720 11 NC_000011.5 36410525 C T ACAGAATTAATGATAATGGTAGTGACGGCTAACATTTTCAAGCACGTACAT 0.427 COMMD9-[FLJ14213]-TRAF6
1686926 rs10838121 11 NC_000011.5 43514379 A G CTTACATAGAAGGGAGGGTGTTTGAAATAAAGGATAGTTATATTAGGTAGG 0.7438 TTC17, LOC120449 [ ] LOC143970,
LOC387762
1689616 rs17725617 11 NC_000011.5 46168067 C G TGTGGTTGGCACTGAAACCAGCAGGCAAGACCAGAGAGTAAAGAAGCAAAA 0.712 LOC401679 [ ]-CREB3L1
1703484 rs11236931 11 NC_000011.5 70195793 C G CAGCTATTGCTTATGCTCCACGCACCATTTGCCCTTTTGGAGGATCATCGT 0.5501 EMS1-[SHANK2] LOC399921
1705437 rs1670543 11 NC_000011.5 73316618 A G ACTTACTGAAGTCCAAAACCAAGCTAAGTACATTTGTTGTCAAGTGAGTTC 0.5779 E2IG2, MRPL48 [FLJ11848]-TSARG6
1709425 rs17755728 11 NC_000011.5 78740181 T C AGAGCCACCATTTCCTTGACCTAATTTGGACTCTTCTCAAACTCACCACAA 0.8514 ODZ4-[LOC387795]-LOC390227
1711184 rs2448281 11 NC_000011.5 79851900 A C AGTTGTCCATGAATCAGTATTTGGGCAACAAAATCACTATACAACCCTGCT 0.7048 LOC390227-[ ]-MGC33846
1718318 rs580459 11 NC_000011.5 85162808 T C AATGGATGAGAATCTTCTGCAGCCATCTGAATCAAATTCTGTGTGCTTAGC 0.337 FLJ38159 [SYTL2]-MGC34732
1718389 rs537604 11 NC_000011.5 85200191 T C TCATCACACGGTCTCAAATCCCTACTTACTCATGTTTGTCTCTTGCCAGTT 0.2944 FLJ38159-[SYTL2]-MGC34732
1718430 rs11234410 11 NC_000011.5 85223048 C T AGTCCGCAGGAGCTTAAATGAGGCTCATGGTCTGGACTGGCTGTTTTCCTC 0.711 FLJ38159-[SYTL2]-MGC34732
1718464 rs930592 11 NC_000011.5 85235182 C G TCTATACCCACTGATCTCAAGACCACAAAGTTTTTGTTGTTGTTGTTGTTG 0.6121 FLJ38159-[SYTL2]-MGC34732
1737980 rs9326283 11 NC_000011.5 98994639 C A TTCAACCCATCCTGAAATCTGCTGACTGATTAACCCACTTCAATCCAGTCT 0.9498 LOC390246-[CNTN5]-LOC401706
1744345 rs11226307 11 NC_000011.5 103746211 G C GAACTTCTTTAACAGGTTCTGAGTAGAAACATAGCTCAATGAAGAAATAAA 0.6622 PDGFD-[ ]-CASP12P1
1749997 rs17655140 11 NC_000011.5 109740440 G T ATATGTATGAAAATAGATTCTAAAGGTATTAGATCAGCAGTCCCCAACCTT 0.6493 RDX [ ]-FOX1
1751158 rs2177745 11 NC_000011.5 111777753 C T CTGTTTCAGTTCTATGGCAGTAATTCAAGTAAGAGTGAAGACACCCATTGC 0.8679 LOC399951-[ ]-LOC387810
1752125 rs605843 11 NC_000011.5 112662883 T C GGTGATCAGCATGCTGCTGGCCCTATGATGATAAGTAGTGGGCTCTTCCTT 0.7336 LOC387810-[NCAM1]-TTC12
1752273 rs10891539 11 NC_000011.5 112774141 G C GTAACCCCGGGAGCTGAGTGAGAGAGGCTCCTTCCCTTACATCCACATGCC 0.4557 NCAM1-[TTC12] DRD2, ANKK1
1752293 rs754672 11 NC_000011.5 112786785 C T TCCTGGGCCACTGAATTGCCAACTGCGTGACCCAAGGCTCCTCTAAACCTG 0.4574 TTC12 [ ] DRD2, ANKK1
1752882 rs17626940 11 NC_000011.5 113430360 G A CACTGAGTAAGCAGGTGCCTCCAAAGGTCTTACTAAGCCACAGGTAGGAAG 0.7852 HTR3A [ ] ZNF145
1754883 rs11602880 11 NC_000011.5 115860421 G A CAACCCTGGCTGACATGACTCCTTCGATTGCTAATCAGTCCTCAGTCACCC 0.8232 LOC283143-[ ]-MGC13125
1756543 rs572126 11 NC_000011.5 117896813 G A ACTTTAGTACTCTGAATCTCCCGCAGTGTCCAATACTGTACTTTTTTACAT 0.1946 FLJ11783 [MLL] FLJ14399,
LOC143941
1760288 rs1228402 11 NC_000011.5 121289130 G A GCAGTGTGATAGCATAAGTCACTTAATCTTCACAATGCTCCTTTGATTCTC 0.6621 SORL1-[ ]-LOC255849
1760335 rs481562 11 NC_000011.5 121223675 G C AGTTTTAGGAACCTAATTTTTTTCAGTGGTCAATTTTGGCTTACAAACCAG 0.6477 SORL1-[ ]-LOC255849
1771665 rs16951805 18 NC_000018.5 7448205 C T GCCTTTAGAAACGCAGGTTCTGGGCCGCTCACCCCCATTTCTGGAGCTGCA 0.9609 LOC339291-[ ]-PTPRM
1778519 rs12327306 18 NC_000018.5 13120681 C T ACTGGGTGCAGCCAGATTCTGCTTACGTTTTGGTTGCCCCATGAAATCGCC 0.6591 SEC13L-[ ] LOC401892
1790542 rs1532234 18 NC_000018.5 25435619 C A CCCAAGAAGGTATTTCTTTGTCTAGAATCACCATATAGCTTATCTTGGTCT 0.0819 LOC390844-[ ]-DSC3
1793653 rs985492 18 NC_000018.5 27563021 G A TCACTATATGTTGGCCTTGATTGGTGTTCCTGAAGTCTTTTGGGCATTTCT 0.4697 LOC390845, LOC390846,
B4GALT6 [ ] MCART2
1798659 rs17740100 18 NC_000018.5 32042471 C G GGTTTGCCTTCTTAAATATGTTATTCTAGGTCATTGGTAACATAAGTTTTA 0.9203 STATIP1 [MOCOS]-RNU4P3
1800398 rs9955296 18 NC_000018.5 33408524 C A CGTTCTCCCCTTCTTAGCTTCGACTCGCATTCTCATGAACATCTCTCCTAG 0.2339 BRUNOL4 [ ]-LOC388474
1801860 rs1866524 18 NC_000018.5 34538449 T C GTCTATTCATCTTCACAGCAATCTATTTCAAAAGTGCTTATCTCTGCTGCT 0.6251 BRUNOL4-[ ]-LOC388474
1803884 rs9960298 18 NC_000018.5 35781021 A G CACATATTTTCTCTTGCAAGTTCGTATGATTTGCATTATTTAAACTTGCAA 0.9862 LOC388474-[ ]-NPM1P1
1804744 rs16973101 18 NC_000018.5 36172105 A G CTATTACAGGACTCCTCATAAACGCAGTGAAGCTAGAGTGAAAAATAGATA 0.9591 LOC388474-[ ]-NPM1P1
1811387 rs9675482 18 NC_000018.5 40075524 T C ACTTGCTAATGAATTATAACATCAATTGTGTATCAACAAACAATATTTAAT 0.7345 SYT4-[ ]-LOC342732
1811405 rs12957915 18 NC_000018.5 40091672 T C GAAGTGATAAAGTGTTGTGAGTAACCCAGCTTTCTTAGAATTGAAACAAGT 0.7391 SYT4-[ ]-LOC342732
1811416 rs1456608 18 NC_000018.5 40104086 G T GTCTCAGTCCTGTTTAGGTTTATAGTTTTAATGTAGGGCAGCAGGGATCTT 0.7247 SYT4-[ ]-LOC342732
1812391 rs17727782 18 NC_000018.5 40843071 T C CAATCTGTTAAGGGTAAATAAGATATAAACACGTGAAAACATAAATCACAA 0.9769 LOC400548-[SETBP1]-
LOC400649
1812844 rs12326596 18 NC_000018.5 41022861 T A ATTATAAACTAGGTCAATTTTCTGCTACTCCATGAGGCCTTTTTTAGAAGG 0.69 SETBP1-[ ]-LOC400649
1813965 rs3760585 18 NC_000018.5 41554413 G A AGATTCACTACACACCTTCAGCCCTGACCAGTGCGACTGAGGCAGAAGGCT 0.7989 SLC14A2 [ ] SLC14A1
1816467 rs16948949 18 NC_000018.5 44014628 A G TTATCTAAATCCTAGTAGAGAATCAATCTAAGTTAACCCACACTTTGGTGT 0.9881 LOC201501-[ ]-K1AA0427
1829453 rs12958775 18 NC_000018.5 55268427 A G GACTGCTAGCATCTCCTTCTTGGCTAATGTTTATTTGGGCAGATGTCCTAT 0.5852 LMAN1-[FLJ30681]-LOC219542
1833522 rs7234317 18 NC_000018.5 59955049 T C AACTCAACCACCACTTATTGTTTTTTGAAGATAATGTTGGTCGTGCGCCTG 0.3892 SERPINB8-[MGC39571]-LOC400654
1835296 rs1942822 18 NC_000018.5 61473241 T A AGAAATTGTACGAAGTAGATGCAAATAGTTCATTAGGACTACTAAGTATGA 0.8468 LOC400654-[ ]-CDH7
1839162 rs11240777 1 NC_000001.5 838822 G A TGATAGCATTTGGATTGGGCTTTAAGGTATGACTAGGAGCTTACCAGATAG 0.7772 LOC284591, LOC400728,
FLJ22639 [LOC388579]-LOC388580
1863938 rs11779336 8 NC_000008.6 10711588 C T AGCCAATCATTTTCCCACAAAGTTACGATACAGCATCAACCACTGGTGTCT 0.9195 SOX7-[PINX1] LOC389624
1868867 rs12679640 8 NC_000008.6 14038640 T C AAATATTTTTTACACCTCATAGTCATTCAAATAGGTACACGTCCTTTTTGA 0.9251 FLJ25402-[SGCZ]-TUSC3
1871356 rs6530875 8 NC_000008.6 15353466 T C GCTAAACAAAGAGACAGATACCTAATCATGGGTACTTTCCCAAGGAGAAAT 0.4542 SGCZ-[ ]-TUSC3
1871489 rs17657878 8 NC_000008.6 15454569 T C TGAAGTAGGAGTCAGGAGAACTGAATGCTATTGAAATAGCTGTCACTCATA 0.768 SGCZ-[TUSC3]-LOC137012
1871506 rs17657927 8 NC_000008.6 15461887 T C ACTTTGGCATGTACTAACGATACTATATTATGAGATATTTTATGTATCCTT 0.7668 SGCZ-[TUSC3]-LOC137012
1871599 rs13279752 8 NC_000008.6 15520159 G C CTGTAAAGAATCTAGCCTACTAATTGTATATCACCATTAGTGAACATTTTT 0.8129 SGCZ-[TUSC3]-LOC137012
1871685 rs17121887 8 NC_000008.6 15610929 G T GTCTGCTTTTGTAAGATTGTTAATTGTATAACCCCAGATTTTCAAGTGACA 0.8203 SGCZ-[TUSC3]-LOC137012
1872350 rs7012344 8 NC_000008.6 15950245 C T ATGCAGGAGCAAAAGCAGCACGGTTCGAGGCAGCGGAAGCATTAGGTATCA 0.419 LOC392202-[ ] MSR1
1899724 rs2589757 8 NC_000008.6 35391245 T A CGTATATTGCACACAAAAAGATCTCAATTAACAACATCTCTCGCTCTGGAT 0.2072 LOC389646-[ ]-UNC5D
1899741 rs2579884 8 NC_000008.6 35398315 C G CATTTTTTTTTTAAGAGGTGCTGTTGTTCATTCTCACATGAATTAGAGAGA 0.2062 LOC389646-[ ]-UNC5D
1899780 rs2589349 8 NC_000008.6 35420609 G T TAAATCAGTTCTTGAAAAAATAGCTTGAGGCTCATGCAGCTTTGGAAACTC 0.205 LOC389646-[ ] UNC5D
1905516 rs2920126 8 NC_000008.6 41513375 T C TTTCCTTTCCCTTTTTATGGTGTTTTTATGGTGGTTAAGAGCGGGAGCTTC 0.7262 DKFZp586M1819 [ ], ANK1,
FLJ25169
1912331 rs6982235 8 NC_000008.6 53442022 C T ACTGAGACTTTTCTTCATGCTACGGCCTAACTCGTCCCCTCTCCTTCCTAT 0.7981 ST18-[ ]-LOC389658
1912900 rs6473754 8 NC_000008.6 53797031 C G CCAGTGTATATTGATCTAATGTTCACTAATACTCTTAGAAATTGATACTGA 0.2608 RB1CC1-[ ]-GPR7
1918804 rs16923384 8 NC_000008.6 59317982 C T TGAAAAGAATTATTGGCCAGAGCGACCCATAGTTGTTTTTGCTAATGTGAG 0.7225 MGC39325-[ ]-LOC137886
1918812 rs4413762 8 NC_000008.6 59320126 A T TCCAGGTGTTTCATCATTTGGTAGCAGATAACAATTCCAGCCTCTGCTAAC 0.7634 MGC39325-[ ]-LOC137886
1919024 rs10110111 8 NC_000008.6 59507136 T C AGGAAAGCAGAATTCAACACATCTTTGAAAGAAAATCCAAATGCTGTATTA 0.6858 CYP7A1, LOC137885 [ ]
SDCBP, NSMAF
1921315 rs2242156 8 NC_000008.6 61151123 C T GTTGGACACTAGGAACTGTTATACACAAGGGAAGTCCAGGACCTCTCTCCG 0.6684 TOX-[ ]-CA8
1923923 rs1384683 8 NC_000008.6 63219918 C G ATTAACTAATACTTCATATTCTTTACGCTGAAACCTAATTTGTTTTTAATT 0.3534 LOC392226-[FLJ39630]-GGH
1929382 rs11781537 8 NC_000008.6 69633631 G A AAACAGCTGTATCTAATACTTTAATGGCATGTTAGAGCTAAGTAAATAGTA 0.8355 FLJ12987-[VEST1]-LOC389667
1933844 rs6984682 8 NC_000008.6 73109526 A G AAGGTTTGGAATCAAGGTCATGGGTAGAGTTGGCATGATGGAAGAACGGAT 0.8253 TRPA1-[ ]- LOC392232
1943237 rs1530050 8 NC_000008.6 81945830 T G GAAGGATAATTTTATTTCCAGATGATTATTTCCAGTTTTTAACGTGAAATC 0.6467 CKS1A-[PAG]-LOC392238
1953067 rs17733523 8 NC_000008.6 92846817 C T TATGTTGGCTAGCTGCATGCACAGTCTTCTCTTGAAGAACGTCTACATTGG 0.7695 SLC26A7-[ ] MRPS16P1
1953110 rs1838184 8 NC_000008.6 92903068 T C TAAGTTTGACAAGCACTATTTGCCATATCACATTCTTGGAAATTCACAGTG 0.8058 MRPS16P1 [ ] CBFA2T1
1953274 rs17748153 8 NC_000008.6 93241264 C T GATAAAGATCTGGATGGAGAATGCCCGACATATGTGCAAATTTGTGCCAAA 0.7306 LOC401470-[ ]-LOC286144
1953297 rs11775813 8 NC_000008.6 93255461 A G TAGGATCCTGCAGTTAATAATGGCCAGTGGCACTGATGGTCATTAACGTTC 0.2657 LOC401470-[ ]-LOC286144
1962816 rs34179481 8 NC_000008.6 103201536 A C ATGTCCCTT1AGAGCCTCTCTGATAAGATTGCTGGAATGAATAAGCTACTG 0.4743 NCALD-[RRM2B] DD5
1966340 rs10093110 8 NC_000008.6 106521997 G A ATATTACTGCCTACCCACATATTTCGTCTTCTCTATTTCTCTATAATAAAA 0.5745 LOC402348-[ZFPM2]-LOC346887
1966361 rs4734877 8 NC_000008.6 106534615 A T AAGTAACACTATAAACCTTGGCGTTAGGGGATTTTTACATGCCTAAATTTG 0.3899 LOC402348-[ZFPM2]-LOC346887
1966373 rs1470684 8 NC_000008.6 106540455 A G TGGTTGTAACAAATATTGTGCCAGCATTATGAGGACTTAGCATCAATCTCA 0.41 LOC402348-[ZFPM2]-LOC346887
1970899 rs2703389 8 NC_000008.6 110513466 C G GCTAAGACATGAGATTCCATTATCAGTAATGTTATTCCTGTAAGTGTGTGC 0.2073 PKHD1L1 [EBAG9] FLJ20366
1971980 rs11995209 8 NC_000008.6 111664622 T C TGCCTTTTGGCCCCTGTAATTTAGTTAGTCTCTGATTTTATCCTAAGAGTA 0.2157 LOC392262-[ ]-CSMD3
1974303 rs1566835 8 NC_000008.6 113975723 A G AAGGCCCTGGACATCCCATGACAAAATTAGCTTAAATGTCAGGACCAGAGA 0.4432 LOC392262-[CSMD3]-TRPS1
1974329 rs17660742 8 NC_000008.6 113988522 G C AAATTGATATCCTTATT1CCAGAGTGAGACTGTACAGTTATTTTCTTATAC 0.7984 LOC392262-[CSMD3]-TRPS1
1974401 rs9297488 8 NC_000008.6 114045624 T C ATTTTATTGTATGGTAAAGTCAAGGTAAACAATTTATAACTATAATGTCAC 0.4412 LOC392262-[CSMD3]-TRPS1
1974421 rs7840935 8 NC_000008.6 114060938 G A TATGTAGAGCTTCGAAATCAATTAAGTTCCTTACAACCTCTGACATAAAGC 0.4442 LOC392262-[CSMD3]-TRPS1
1974444 rs6999828 8 NC_000008.6 114071268 G C ACTATAAAACGTTTTCATGATCCCTGTTCTCATGGAGTATTCTATTAGTGA 0.4442 LOC392262-[CSMD3]-TRPS1
1974476 rs2356050 8 NC_000008.6 114103495 C T AAGTAAACCAGGTAGGGGTTTTCAACAGCCTTTATATTTACATATGTATAT 0.443 LOC392262-[CSMD3]-TRPS1
1974527 rs17607120 8 NC_000008.6 114176761 C T TGATTTCAGAATGGGGTTTGGCATACGGCCAATGATTAGCTCTCTGCATAT 0.4546 LOC392262-[CSMD3]-TRPS1
1975561 rs17641691 8 NC_000008.6 115433400 G A CAATTGTGTGGTATGCAATATGTTCGTAGTAAACAATTCAAGTAGCACAGA 0.8546 CSMD3-[ ]-TRPS1
1982441 rs17818446 8 NC_000008.6 120790094 T C TGCTGCCCTTAGCCACTGGCATAACTGCAAGCCTCTCGGGTCATCTAGCTT 0.911 ENPP2-[TAF2] MGC5528
1988046 rs17395997 8 NC_000008.6 125889640 T C TGATATTAGATGATGGTAATTTAAATTTAGAGCAATGGCTGTTCTGGGAAC 0.3968 MTSS1-[LOC392270]-ZNF572
1988073 rs1427083 8 NC_000008.6 125901530 G A TTCACTTTTTGTCAGTTCATGCCCTGTGGTAGGTTCCCCATATACAATGAG 0.3838 LOC392270 [ ] ZNF572
1992022 rs2648834 8 NC_000008.6 129128085 G A CTGGGGAAGCCCCAGCAGATGCCTCGATGTGAGTGTTTCTGGGATAGTACA 0.4415 LOC389686-[ ]-LOC401476
1992318 rs3815871 8 NC_000008.6 128965167 G C TGCTGTGAGTAATAATGACTCTGCTGGTAATTTGTGTCCTTCTGCTTGGAA 0.6515 MYC-[PVT1]-LOC389686
1994975 rs10956535 8 NC_000008.6 131511350 T C GTAAACTCTAGTTCTGTGTCATATCCGATGGGGAAAGGGTTCCACCATTAA 0.619 HSPC054-[ ]-ADCY8
1999459 rs10956699 8 NC_000008.6 134245172 G A AACAAAAATGTGAGGAATTATCTTCGCAGGGAGCAGATAAACTATGCTTTC 0.5174 WISP1 [NDRG1] LOC392271
2001950 rs6577889 8 NC_000008.6 135821603 G A CAACAGACAAAATGCACTAGCAACTGGAGAGGTGAGTTTTGTTAAATTACA 0.6749 ZNF406-[ ]-LOC286094
2001971 rs10112307 8 NC_000008.6 135835535 A G AGGAGAGATAAATATATAAGCAACAAGTTATATTGGAAATAAAACCCATGG 0.6905 ZNF406-[ ]-LOC286094
2009288 rs7295775 12 NC_000012.6 2647666 T C CACACCTGCACGCCTGAGCAGACTTTCGAGCAGGGCGCAAAGTTGGGTGGC 0.9461 FLJ11117-[CACNA1C] LOC283439
2009302 rs4765968 12 NC_000012.6 2658111 T C TCCGTCTCTTCCTCATCCTTATTCTTGTCACTGGGAGACATTCGTCACTGA 0.9504 FLJ11117-[CACNA1C] LOC283439
2011187 rs7980515 12 NC_000012.6 22995946 A G AAATGCAAGGAATGACAAAAGAATGAGTGCTTCATCCTAGTTTCTAGGCCT 0.2039 EKI1-[ ]-SOX5
2013955 rs12230476 12 NC_000012.6 17716456 C A CATATTACCTTATTATCCTACAAAACAAAATGCATACTCAATAACATTAAT 0.6949 LOC390298-[ ]-FLJ22655
2016686 rs4762694 12 NC_000012.6 21068254 A G CTGCATCCCCTCTTTTTCTCAGCAAACACTCTCAAGTCTCTCCCATCTATT 0.3262 SLCO1B3-[LST-3]-SLCO1B1
2020226 rs7296211 12 NC_000012.6 24864227 T A TAAACACTTTCACCATTAATAACAGTTCATTGGCATTTTAGCAGATCTACA 0.2869 LOC387846 [BCAT1]-LOC196415
2021615 rs16929857 12 NC_000012.6 26042998 A G TATGTGTGGGCGTGTATGTGTGTCCATTCATTTAAGGAAACTTGGAAAATA 0.8188 LOC283347-[C12orf2]-BHLHB3
2022897 rs4304878 12 NC_000012.6 26942203 G T TTTCAATATACACCAGCTGCTAAATGTAGTTTCTATTGAATATTCAGACAG 0.2215 LOC341370 [ ] DKFZp564O1863,
FLJ10637
2022921 rs2029309 12 NC_000012.6 26972833 C G TAAACATGTAAACATGCTGTCTCTACTATTCTGAAAAACTACAACAGGATT 0.2214 LOC341370 [FLJ10637]
DKFZp564O1863, TM7SF3
2022927 rs708158 12 NC_000012.6 26978970 T C TTTTATAGTTACAGAATGTGTAGTATATGCCAGGTGCTATTGCTGGCACTG 0.2237 LOC341370 [FLJ10637]
DKFZp564O1863, TM7SF3
2024965 rs4362217 12 NC_000012.6 30367273 T C GGGGCAAAGATGGGGATTAGAATGATGACATTGCAAAGAAAGTATCATCAG 0.8593 ARG99-[ ]-IPO8
2027435 rs7306057 12 NC_000012.6 33030513 C T TCTACAACCGGTTCAAGGGCCACAACGACCTGATGGAATACGCAAAGCACC 0.4815 PKP2-[LOC283343]-SYT10
2027772 rs10506102 12 NC_000012.6 33105304 G C GTTTTGCTTTACATAGCCAAATTAAGTACCTGAAATAAAATATAGAATATA 0.5491 LOC283343-[ ]-SYT10
2030091 rs11171720 12 NC_000012.6 37996740 C T TTGAGGAGAATGAGGATATGGTGAGCGTTAGCATAGAATGTAACCTGAAAC 0.8193 LOC121216-[KIF21A]-LOC390306
2032297 rs1997192 12 NC_000012.6 40025711 T G TCTCAGTTGCTTTTAATCTACTTCTTTTGGGATAGAGAGAGATGAGTTGCA 0.08 CNTN1-[ ]-DKFZp434B0417
2034022 rs11837562 12 NC_000012.6 41580383 A T TCCCGTCCTCCTGTGCTGTAAGCTCATCTTCATAACATAATGTTTATTTTT 0.7507 LOC390308-[ ]-MRPS36P5
2037647 rs2731099 12 NC_000012.6 47170193 C T GACATAGCAGAGGGCCAGAGGGCCACAAAGAATAAAAGATGTGAGGCCTTG 0.6249 LOC390312, ANP32D [MGC35033]
LOC341568
2038957 rs4761981 12 NC_000012.6 49960768 T C CTTTGTATCCTTTCAGTTTCATATCTTCCTCTCTTGTGCTCAGACCCTTAC 0.1545 DAZAP2, LOC57228 [ ] ELA1,
BIN2
2039518 rs17126450 12 NC_000012.6 50894979 C T TGGGATGGAGGAATGAATGAAGAAACGGTGAGGCTGGGTGAGGTGGCTCAC 0.7735 LOC144501, LOC283403
[LOC4017219 KRT7, KRTHB@
2039526 rs7314387 12 NC_000012.6 50900229 T A TAAAGTACCAAATTTCATGAATAACTTCTGCAAAGGAGAACCATTTATTTA 0.7822 LOC144501, LOC283403
[LOC401721] KRT7, KRTHB@
2040404 rs1894033 12 NC_000012.6 50981897 T C AGAGGTGCAAGTAGTGAACGCCTGACGCCCCGACCACTGTGCTCTCCATTC 0.148 KRTHB@, LOC387859 [ ] KRTHB@
2041414 rs7297602 12 NC_000012.6 52359171 T G AGGTCACCAAGGAAGGGTTTTGATTTGTTTATATATGTTTCTTTGGACAAG 0.5091 ATP5G2, ATF7, LOC341412 [ ]
KIAA1536
2041419 rs11611695 12 NC_000012.6 52340028 T G GGAAGAATTAACCAAAAGCCATTCATGAGTGACTGGAACCCAGGATTCTGG 0.849 LOC341412 [ATF7] ATP5G2
2048484 rs10877864 12 NC_000012.6 61179466 T C GTAATTTAACTGAACTAGTCTCCTATTGGACACTTGCATTCTGTTCAGTGT 0.8421 USP15-[KIAA1040]-FLJ25590
2049385 rs7973936 12 NC_000012.6 62619912 G A ATGGAGAGATTGAACCTAAAGATCTGTAAAGTCTCTGCAACTCTCAAGTCC 0.6824 LOC341315-[SRGAP1]-FLJ32549
2054953 rs7135345 12 NC_000012.6 68573193 G A CATATTATTAAAACTCTTGATGTAGGCCACCAGTTGCTTTCTAGAAAGATT 0.8842 RAB3IP-[ ]-FLJ25056
2056311 rs11178491 12 NC_000012.6 69603195 C G GTTAGTTCAGCATGGTAAAAATAACCCTGAGTGGGCTGTAATTTTGGTGAC 0.7763 PTPRR-[ ]-TM4SF3
2056363 rs17814619 12 NC_000012.6 69659996 A G ATGTTTATGAAAGCACATACAGGCAATAACAGTGCTAACCTTCAGAGGTTA 0.7863 PTPRR-[ ]-TM4SF3
2060561 rs17112159 12 NC_000012.6 71903355 T C CCTTCCCTGGCTGTATCTGCCTCCTTGCCACAGGTTATCATTATTCTAAAT 0.9729 TRHDE-[ ]-VENTX2P3
2063822 rs10778227 12 NC_000012.6 77734860 A G TAAATAGAATAACATGGATATCAAGAGGTTCTTAATTTTCATATTTCAGAT 0.4645 LOC390347 [ ]-SYT1
2083902 rs7972172 12 NC_000012.6 103076762 T C GAGAAGCTGTCCTTAAATGGGGGTGTCCGGGAGTCCTGACGAAAGATGAGC 0.2649 NFYB [ ]-LOC400068
2084108 rs4964287 12 NC_000012.6 103212026 C T GATTTCTCAATGTTGTTGTAGGTCTCGGAGGAACATGTGTGAATGTGGGTT 0.6959 LOC400068 [TXNRD1]-CHST11
2097268 rs1023229 13 NC_000013.6 18068925 G A GTCCAAACATACCGATACAAAAACAGTTACATTATTTCATCTCATACTGGT 0.1527 HSMPP8 [PSPC1]-LOC390377
2099207 rs7325032 13 NC_000013.6 20545054 C A AATAAATGACTTTGCACATAATTATCCTTGGTTTACTTCTTCTCAGCTGCA 0.5647 FGF9-[ ]-LOC387908
2116144 rs9532890 13 NC_000013.6 39914031 G A TTCACTCTTTTGGAAGTGTTTCTTCGTGCATGCCCCCACTTAAAAAAAAAC 0.395 RGC32 [ ] KIAA0564
2118459 rs35665055 13 NC_000013.6 42892501 T C TGCTGAGGGTACACATATGACTAGATACAAAGCTGTCCACTTGATCTACTA 0.8688 LOC400128-[TSC22]-LOC400129
2118498 rs9533910 13 NC_000013.6 42935937 C A AAGAAACAATTTGTAAAACTGTCTCGGCGAATTCACTTAACCAAAACTTGT 0.8718 LOC400128-[TSC22] LOC400129
2118500 rs9525983 13 NC_000013.6 42946257 C A TGCTGTTGTACATACTCTGAAGCAGGATTTTGAGTCACTGATTTGACATGG 0.8716 LOC400128-[TSC22] LOC400129
2128119 rs17623690 13 NC_000013.6 57602026 A C TTCATAATCAGTAATTGTTTCTCAGACGTGCTTGATTCTGGAATCTCTTTG 0.7394 LOC341689-[ ]-DIAPH3
2129919 rs9285228 13 NC_000013.6 59162157 T C TCAGTCACCAGCATGCCAAAACCATTCTTAGGAATTGCCCAACAGACCCTG 0.7155 LOC390407-[ ]-LOC387932
2129930 rs9538922 13 NC_000013.6 59164839 T C ACCAGCTATGCTACCATTTCTACTCTGTTTATGCCTACTAAGAGGGCTTGA 0.7194 LOC390407-[ ]-LOC387932
2138144 rs17084398 13 NC_000013.6 67326957 C A GATCTTTAGTACACAGTCTATTAATCCACTCAAAACCCCATGATTATCCTA 0.7108 LOC338862-[ ] LOC387906
2140871 rs1543663 13 NC_000013.6 69899703 G C CCCTGAAAAGTTGGTATTTTCTTCCGTATCGGTCCTTCATCATTGAACATG 0.0303 KLHL1-[DACH]-FLJ22624
2142435 rs9318170 13 NC_000013.6 71738727 C G CATTCACCTATTGTTCCTTGGAGACCAGTGACATTGATAGGGAAAATACTC 0.0188 LOC387934-[ ]-LOC122134
2147441 rs9530848 13 NC_000013.6 77397109 C T AGCAAAAGGCAAAATCGACTAAGTGCCTTGCCTTCCTCTTAAGTTGGTAGA 0.7698 LOC390415-[ ]-C13orf10
2147936 rs3861143 13 NC_000013.6 78288603 G A TATGCCACCTTCAAAAGCCTACCTCGTAAAAATTCTTCCTCTTTAGCCTGC 0.818 NDFIP2-[ ]-SPRY2
2147954 rs3966634 13 NC_000013.6 78381457 A G TATAATGATAGTGATTGTTTCCTATATATCACAATTTGGAGATAAATAATC 0.8333 NDFIP2-[ ]-SPRY2
2153874 rs9531941 13 NC_000013.6 84511763 T C ACTGTAATCATTCCAGTGAACAGTGTGGGTTTTTCTCAGAGACTGATGGGC 0.2623 SLITRK6-[ ]-LOC390417
2159712 rs9516282 13 NC_000013.6 92098288 C T AATGTTTTAAAGTACAGTATTTGCTCGATGAAAATATGATGTTGTGACTTG 0.655 LOC400151-]GPC6]-DCT
2163321 rs17475472 13 NC_000013.6 98981498 A G GTAAATGCAAGAAAGTGAGAGTATCAGTTATGAAAGGCACCTTTAATACCA 0.7929 LOC400156-[FLJ14624]-LOC390423
2163423 rs16957615 13 NC_000013.6 99075795 G C AGAAGGACAGGAATTTCCACCAGCAGAGCCCCTTAAGAAGGTTATCTGGGA 0.9268 FLJ14624-[ ]-LOC390423
2168345 rs9519072 13 NC_000013.6 101865262 C T CTTATCATCCTTAGCATTTTTTAGACGGCCAGATTTGGAGTTTAATACTAG 0.1917 SLC10A2-[ ]-G30
2170305 rs4771480 13 NC_000013.6 102920777 A G TATTCTCAACAGATCTCTCCTGACCATGCCGTTCATTGCCCTTGCTGTCTT 0.7975 SLC10A2-[ ]-G30
2172827 rs9520083 13 NC_000013.6 104818492 G A AAAAGGCAGAGATTACAACCGAAGTGTTTTCCTTGACCCGGGAAGTGATCG 0.3643 LOC341604 [ ] EFNB2
2199587 rs12355804 10 NC_000010.5 3489854 C T TAAATACTGTCTCAAGGTTGGTTAGCGCTTTCAGATGAAGCATCTCATTTG 0.9184 PITRM1-[ ] LOC387631
2201976 rs1132293 10 NC_000010.5 5685044 C T CAGAACTGGTAACTAAGGCGGTGATCAAACAGGAATGCTTTTCTTCTCAGT 0.6946 CALML3-[ASB13] LOC399712
2203902 rs2497469 10 NC_000010.5 7165641 C G AGACCTTGAGAAACGCTTCCAAAAACTGCAGGAATGATTTCTGAAGGCTGC 0.7852 PRKCQ-[ ] SFMBT2
2210865 rs1556718 10 NC_000010.5 13330966 C A TAAGCTAATCATACCTCCCACTCTGCATCTGAGCAGGGTATCTGAGACTCC 0.7265 LOC221044-[PHYH] SEPHS1
2212327 rs1041337 10 NC_000010.5 14354736 A C ATCACTATTTGTTTGAAAACAATGTCCTGATACCCTGCTGTCTTCCCAGTA 0.4528 PRPF18-[FRMD4]-C10orf45
2214222 rs10737009 10 NC_000010.5 16090179 A G CCCTGATGACCTGGTCAATAGAAACAAATGAACACGTGACTTGCATTTGAG 0.2466 FLJ13397-[ ]-PTER
2222231 rs17440393 10 NC_000010.5 23241574 G A AAGACCATCAACATCAGACAATAAAGGGCAGTGACCACTGAGAGACGGGAA 0.7748 PIP5K2A-[ARMC3]-MSRB
2223295 rs10764444 10 NC_000010.5 24304727 G A GTTGGGTTGTTCCCGTGGGTTGACAGTCAGCATGTTTTTATTTATTAAATG 0.9209 LOC220213-[ ]-KIAA1217
2228591 rs2250755 10 NC_000010.5 29293136 G A ACTTTGAGGCAGTAAATGTGAGGCAGTGACATACATACCTCCTTGTAATAG 0.5157 LOC256457-[ ]-MGC33408
2236226 rs1192668 10 NC_000010.5 37150953 T C GCTGAGTTTGAGACTATGTTACAAATGTTTATCCTCAATGACATATGAGAA 0.1346 LOC387651-[ ]-LOC389948
2244319 rs10826075 10 NC_000010.5 50871973 C G AGAAAGAGAGTATTTGGTTTTCCAGCCTCTTCAGGAGGAGGTTACTGGGGA 0.7651 LOC255319 [ ] MSMB, NCOA4
2246661 rs293267 10 NC_000010.5 52556116 G A TGTGGATTAACTGTGCTCACAATAAGTATTTGTATCATCAATTGCATGACT 0.6759 ACF-[PRKG1]-CSTF2T
2254679 rs7913866 10 NC_000010.5 58867791 C T GATTTTGTAAGAAGCAAAAGTAATATGAGAACATGATCAGCTGATGGCTTA 0.8559 ZWINT-[ ]-MRPS35P3
2257769 rs2127355 10 NC_000010.5 61878819 A G GATCCTCATTAGTCCCAAGGTTGACATATGAATCTCTTCTCCCTACACCAT 0.5225 LOC387684-[ ] CDC2
2267426 rs1015193 10 NC_000010.5 72929029 T C CAAGAATATTCAATGGCCAACATATTTTTAGGCAAAAAATGCAAACTACAA 0.5149 CDH23 [PSAP]-CHST3
2274606 rs4933449 10 NC_000010.5 89051019 G T TGGAAAACATTAGAAGAGGGTTCCTGTGTCATAGTTTCAAAATTCTTTTCA 0.6675 MINPP1-[ ] PAPSS2
2275497 rs10788549 10 NC_000010.5 81722565 G A CCTTTCACCTGAGCAAGGCATAGACGATTCATTCTAAAAAGTGACACTGGG 0.6063 MAT1A, LOC143243 [ ]
LOC143241, MGC16186
2287160 rs7910115 10 NC_000010.5 92858313 G A CACTAAAGATAACTTTATAGAGAGGGGACTTTCAAATATTTCTATAACTAG 0.9659 MGC16202-[FLJ37306]-LOC387702
2298521 rs11192851 10 NC_000010.5 107790907 A C AATTAGGAAAGGAAGAGGTCAATTAAAATTACTAAGTAAGGCATTAAGACA 0.5947 LOC86123-[ ]-SORCS1
2311188 rs1937819 10 NC_000010.5 122173898 A G AGAATACACTTTTTATTTCAAAGACAAGTAAGGCAACACCCTCCTCCCAGC 0.7381 LOC196051-[ ]-WDR11
2312380 rs10887014 10 NC_000010.5 123316424 T C CAACTGGCAGGTTAATCCCTGTTAATGAGCCCCAAATTTAATTATCTTACC 0.8347 FGFR2-[ATE1]-FLJ20003
2314337 rs841009 10 NC_000010.5 124934127 C T TCAAGGAAGGTGTTTCAAACCAAGACTGATCAAGCAGCAGGAACTGCAAGG 0.8254 LOC390009-[ ]-GPR26
2316249 rs11244755 10 NC_000010.5 127261417 C T TCATAGGTTGAGACTAAGCCATCAACTCCAAGTTTGAAAAGAAAAATAGCA 0.6858 DHX32-[FANK1] ADAM12
2317228 rs10901612 10 NC_000010.5 127719499 C T TGTGAACTTGTAAGGATATTTGTTTCGGGCAAACACCACAGTTGAATGATA 0.6154 ADAM12-[FLJ32938]-DOCK1
2321879 rs9831753 3 NC_000003.6 1851192 C G AACTACTCACCTATTATCCATAAAGCGCCCATGTATTCTACTTCTAATTGT 0.5918 LOC391504-[ ]-LOC391505
2324234 rs1705820 3 NC_000003.6 3201143 C A TAAATCAGGGTAATTCTCAAGTTCCCAGTCTACAGAGGCTACAAACAGTTT 0.2142 TRNT1, LOC51185 [ ]-LRRN1
2328162 rs17215933 3 NC_000003.6 6174813 G A GACATAGAGAAATGTTCAAGAGCTCGTTTGGAAAAGGAGATAGATAGTTCA 0.9414 MRPS35P1-[ ]-MRPS36P1
2328415 rs155420 3 NC_000003.6 6434012 C T ATGGAGTTGGAAGCCCACAGTATTACGGCCTTGCAGTTCTAAGAGCGGGCC 0.6342 MRPS3SP1-[ ]-MRPS36P1
2338982 rs1449533 3 NC_000003.6 16754279 T G GTGGTGGGTGGCGGATGGGACAGATTACTTAGACAGGGTTGCTGTAGACTT 0.2189 DAZL-[ ]-PLCL2
2340118 rs17503281 3 NC_000003.6 18617651 C A CTCATGCTTGAGTTTTAATGGTGGACAAATTATGGGAGGGACATTTCCCCA 0.8848 LOC131185-[ ]-KCNH8
2340592 rs2948099 3 NC_000003.6 20027872 G T AAAGCACCGCAACAGTGTGTTTTGATCTGAAGTCAATTACTTGTATCAGAA 0.1734 RAB5A [FLJ25449] PCAF
2342573 rs11914361 3 NC_000003.6 22051102 T C TAGATGTTGGAGCTATCAGATAACCTCATAATTGGTATAATAAAATGTTAA 0.8106 FLJ22419-[ ]-LOC389099
2343282 rs978397 3 NC_000003.6 22742532 A G ACCAGCAAGTCCCCCTAACAAGGCCAACAGGTATTTGCCATAAGAACAGAC 0.9874 HMG1L5-[ ]-LOC391519
2345656 rs2036429 3 NC_000003.6 26506748 T C TGATCATACCCAGTACTCGCTGGTTTTTATTTAATGTAGCTTTGAAAAAAA 0.6354 VENTX2P4-[ ]-LRP15
2345857 rs4973783 3 NC_000003.6 26526758 A T CTCTGAGGCCAGGGCCAGGCCTGTGTCCCAGTGACCAGGTTCAGACTTTAG 0.3611 VENTX2P4-[ ]-LRP15
2349785 rs17350388 3 NC_000003.6 30804527 A G GGCACGTATGCTCACAAAGTACCAGATGTTCTACATATGCCATTCTCTGAA 0.7017 TGFBR2-[LOC339896]-LOC339897
2351093 rs6801121 3 NC_000003.6 33507540 C T AAGTTCCAGTGACATGCCCTAATGCCTCTTGCCATTTTATACATCGCTGCC 0.6134 UBP1-[ ] CLASP2
2354274 rs17733640 3 NC_000003.6 38407367 A G TAATGACTGTATAATATTCTATCTGGGTAGACCAGGCACGGTGGCTCATAC 0.5421 SLC22A14-[XYLB] ACVR2B
2355020 rs1799423 3 NC_000003.6 40166270 G A AGCTACCCAAGTACCTGTCAGCTCTGTTTTCAATCTTACACTTTTCTTTCC 0.5094 MOBP-[MYRIP]-GC20
2358053 rs11130066 3 NC_000003.6 45489589 C T GTGTAATACCCTTAGCTTTATATCTCTCAGTTTTCACACAATGTGTTGTAT 0.3828 RIS1-[LARS2]-LIMD1
2358096 rs2578670 3 NC_000003.6 45534058 G T TTAAATTTTTATTTGCATATTTGTTTTCTATCCTAATTCCCTACTGATCTT 0.6125 RIS1-[LARS2]-LIMD1
2362171 rs7426795 3 NC_000003.6 54370745 T C CTGTGTTTCTCCAAAGAAATGATCACCTTGATAGTTGGTGATTTATATGTG 0.2785 LOC266954-[CACNA2D3]-HT017
2362180 rs7653648 3 NC_000003.6 54364550 G C CTGAGGACCCTGAAGCCACCAGTGTCGTATTAATCGAAACCAGGGACTTGT 0.2975 LOC266954-[CACNA2D3]-HT017
2368729 rs9857754 3 NC_000003.6 60718143 A C AGACCAAATTCATGACATTGTTTCAACCAGTGCAGCTCCTTTCATATTAGT 0.9087 LOC391540, LOC391541 [ ]-
PTPRG
2369244 rs9683298 3 NC_000003.6 61224786 C T GGGCAGTTGGTTATTACACAGAAAACATGTGCAACACTTAATTGACTCAAA 0.9343 LOC391541-[ ]-PTPRG
2370749 rs6807315 3 NC_000003.6 62925331 G A ACACCTTTTATTCATGCAGAGAATCGTGTTCCTCTATCAAAGACCCACAAC 0.1915 LOC389127-[ ]-LOC132205
2372263 rs1561988 3 NC_000003.6 64500596 A G GTGCAGGCTGAGTCAAACTGCTGTCATCACCAGAAGCCTCCATCGGAAGGC 0.7745 PRICKLE2-[ADAMTS9]-BAIAP1
2378362 rs1002200 3 NC_000003.6 70792242 A T TCATTCACAGATTTATTTATGGCCAAGCCACACACCTTTGTGTTCAACTTC 0.5787 LOC401072-[ ]-FOXP1
2379489 rs12486652 3 NC_000003.6 72615814 A G TCAGGGCATGGTTAGTTTCAAATCAATTAAGCTCCTTATGACTTTATGATT 0.4491 LOC339875 [ ]-FLJ10539
2386150 rs9866565 3 NC_000003.6 79916897 A G AGTGGTATATAAAACACAGTTGTTGACCACAATATAACTAAGTTACAGAGC 0.4273 ROBO1-[ ]-LOC391554
2386620 rs3773220 3 NC_000003.6 78622704 C T CTCTGCATTAAAATAATAATCATGGCGAGCAACAGATAAAATAATGTTAAA 0.7214 MRPS17P3-[ROBO1]-LOC391554
2386633 rs6788434 3 NC_000003.6 78654588 G A GTATTATACTTCAGTTTACGTAATCGGGAAAATAAGAGTGGTCTAGAGAAA 0.7493 MRPS17P3-[ROBO1]-LOC391554
2386656 rs17016466 3 NC_000003.6 78675379 A G AAACAGTAACAACAACTGTATTTGCATAAGCACCCCATAATCCACACCCAC 0.7495 MRPS17P3-[ROBO1]-LOC391554
2386667 rs3773240 3 NC_000003.6 78703985 C T CTGCTTTCTATGCTGGGGTGGCAACCTAATCCAAAATTCCTATTGCAGGTT 0.7581 MRPS17P3-[ROBO1]-LOC391554
2386700 rs35077320 3 NC_000003.6 78735232 G A CCTTCTCTCGAAGTTTCTATATGCAGATCATGACTGAATATTGTTGTTTAA 0.7103 MRPS17P3-[ROBO1]-LOC391554
2387552 rs6551427 3 NC_000003.6 87126154 C G CCATAGTGGTTAGTTCTACATTCAGCGAGTGGCTTAAAATTTATGCCAATG 0.3167 LOC285232-[ ]-DKFZP564O123
2392172 rs10511181 3 NC_000003.6 102010763 T G CAAAGAGTTCTTAAAGCTGCTTTCTTGGTAATTATAACTGTTTCAAGGAAT 0.8667 TFG-[TARSH]-IMPG2
2392173 rs2595894 3 NC_000003.6 101998783 G C AAGAACAACCATCTTGTTGCTCCAGGGCATAGGTGAAGATCCGCTGCAGCC 0.1317 TFG-[TARSH]-IMPG2
2393730 rs9851200 3 NC_000003.6 103893209 T G TGAGATTCTTCCCTGCCTTCTTCCATAAATTCATTATATTCTAGCCCTAAT 0.3579 LOC131368-[LOC391561]-LOC391562
2393802 rs345585 3 NC_000003.6 103944914 G T CTAGATAACACACAGCTACTAAATGGTAGGTCAAACTTTTTGATCTATTTA 0.7189 LOC131368-[LOC391561]-LOC391562
2393855 rs344675 3 NC_000003.6 103994849 G A CCTTACATGTATTTCTTTAAATGGCGTAACTCCACCAAAGATGGTTTTGAT 0.3051 LOC131368-[LOC391561]-LOC391562
2393869 rs344668 3 NC_000003.6 104028539 A G TTCTAAAAAATCACAAGCTGTGACAATCTTGACTATAAGTATTAAATTCAA 0.3142 LOC131368-[LOC391561]-LOC391562
2393872 rs1692458 3 NC_000003.6 104034085 A G TTTCTACTTTTTCAACATCAGAAGGATAGATGTAGGACCTGCTGCTTTTTG 0.3152 LOC131368-[LOC391561]-LOC391562
2394342 rs721778 3 NC_000003.6 104592350 T C CCCTTATTCTGTCTTCACGGAAAATTATTATGCATCCCTCAGTTAATACTG 0.8029 LOC391561-[ ]-LOC391562
2399557 rs16856690 3 NC_000003.6 111438775 A G TGTAGAGGCCAGGAAAAGCTTGCTGAATTTAAAAGTCAAGTTTATTCCCCC 0.9763 LOC401083-[ ]-LOC389141
2402034 rs16860899 3 NC_000003.6 114438078 A G AGGCCCTAACTCTACTTGAAGGTAGATTCATGGAGGGCTATGCAGAGATGA 0.8125 LOC402136 [FLJ11142] LOC152185
2402124 rs2399481 3 NC_000003.6 114555885 G C GAAACTTACAGCATATTAACAGACAGTTATCAATGACAAAAACATTAAAAT 0.8033 LOC152185 [ ] FLJ20174
2402372 rs324553 3 NC_000003.6 115047652 C T AAAAGATTAGTTTACTTAGTCTCTACAGGGTCTATTGTAGCCCTCTATTAT 0.7178 MGC42530 [KIAA1407] QTRTD1
2402892 rs4399857 3 NC_000003.6 115647494 T C AAAATAATTTTTCCAAAGAGTTGATTATCTTAGACTAAACTAATGACTCAA 0.7614 FLJ39873-[ZNF288]-LOC344811
2405824 rs10934442 3 NC_000003.6 119230806 C G TTCCCACAGTGGGCCCTGCAGAACCCTCAGATACGAAAAGTCAGCCCTTCG 0.8361 LOC285194-[LOC389142·-IGSF11
2410695 rs2279988 9 NC_000009.6 1032166 G T AAGCAGCTGGGATCTAAGTTCATTTGCATCAGGGCCACTCCAGCTCAGTTC 0.3248 LOC401490 [LOC389702] DMRT2
2415217 rs16926462 9 NC_000009.6 7591812 G A TTCACCCACAAGCTCCTGTTAAAATGCCCTCTTGTTAGACTCCATACCTCT 0.8214 LOC392285 [ ]-MGC4730
2420701 rs1953021 9 NC_000009.6 12904396 G T TGAAATTAAATTATTTTTCTAGTTTGTAGAGGCTATATCCATGACCATTAT 0.3172 LOC286343-[ ]-TDPX2
2425790 rs10963486 9 NC_000009.6 18156934 T C AGGACCTATTGGCGTGAATTAACTTTTGCATTGCGTTAGAAAAACTTTCTA 0.7352 SH3GL2-[ ]-ADAMTSL1
2426484 rs7862714 9 NC_000009.6 18588768 G C GGCCAAGAGCTGGTGGCTGACTAGTGCTGTGTGAGCATGGGTTTATAAATG 0.3772 SH3GL2-[ADAMTSL1]-FLJ35283
2431351 rs4977693 9 NC_000009.6 26103846 G C ATGAATAAGCTATTAACTAAACTGAGTGTGAGTATAGCAATGTATAATCTC 0.6688 LOC389708-[ ]-C9orf82
2437121 rs831274 9 NC_000009.6 33273286 G C TCCTCCTCTCCTTCTCTCAACTCTCGCTGGCCTAGATGTCTCTCACATAGT 0.1601 BAG1, SPINK4 [C9orf83] NFX1
2437138 rs706115 9 NC_000009.6 33243605 C G CTACCTCTACTACCTTGTCTGAGGTCTTAACCTGCCCAGTCCTGAATTCCT 0.8381 SPINK4 [ ] BAG1, C9orf83, NFX1
2446882 rs17084935 9 NC_000009.6 67806625 T A TCTGGCCTATCTCATTTCCAAAAGTTGTGAGACCTGATATCGTACCTATAG 0.8677 APBA1-[LOC375743]-LOC138255
2448996 rs7045535 9 NC_000009.6 70667362 T C TAGACCCCGACCAGCCTACATATTGTTTGCTCTAAGGTCTAGTGCCCTCTC 0.7663 ZNF216-[TMC1]-ALDH1A1
2450638 rs10781268 9 NC_000009.6 73266161 C A TTGAGATATAAACTAAAATTCCCTCCCTATAGGTTTTGTATCTCTTCGTCA 0.4729 OSTF1 [ ]-LOC138932
2451656 rs10869756 9 NC_000009.6 74416460 T C GTTCCCAGTCTGTGCCCATTCACAATTGACTCCAGCACATGAAAGAATTAG 0.7672 PCSK5-[ ] FLJ11149
2451662 rs10869758 9 NC_000009.6 74422495 C T AAACTGTCTATTCATGATTTATGCACTGAGTATTGCAGTCCTCCAAACACT 0.7741 PCSK5-[ ] FLJ11149, LOC158473
2468866 rs7029471 9 NC_000009.6 101782027 A G GTCCTTCCATTAGGAGGTCTGCAGAACAGAGATAAAAATGGAAGCCAGAGA 0.2522 LOC340511-[ ]-SMC2L1
2469246 rs16923908 9 NC_000009.6 102489899 T C AGGCAATTCAGACAAAAAGTTGTGATAGCATAGAAAGCTCACTGGACAGAC 0.983 LOC347281-[ ]-LOC138805
2469920 rs10761084 9 NC_000009.6 102910990 G C CTATTTTCCTCCCATAGATAATTTTGCTCATCGAGCTGAAGTTCGGAAAGC 0.8024 NIPSNAP3A, LOC402374
[NIPSNAP3B]ABCA1
2473163 rs7850283 9 NC_000009.6 107203002 G A ATTTTAGGATGTTGGCTATAAACACGAATCCTTCCTCTATTTGCATGCTGA 0.5256 CTNNAL1 [C9orf5]-C9orf4
2473181 rs7049112 9 NC_000009.6 107225341 C G GGAGGAAAAGATGAACCAACTCCCACAAAGACTGAATAGAAAAAGACTCAC 0.5306 CTNNAL1-[C9orf5]-C9orf4
2473479 rs10512394 9 NC_000009.6 107609061 A G TCCAGGAAGAGAAGCACTTGGTCTCATATCATTATATTTAAGGAGCTCCAA 0.6572 PTPN3 [ ]-LOC402375
2474217 rs1410051 9 NC_000009.6 108397190 T C AAAGATGACAGTGGCAATCAACATATGAGGAAAAAACACTGAGAGTCAATA 0.7447 LOC401546 [TXN] LOC255220
2475055 rs947509 9 NC_000009.6 128426973 T C TGCATCCAGTGCAGCCCAAGAGGCGTCATGCATTCTCTTCCCCTTGTTTGC 0.463 FREQ-[LOC392395]-DKFZp434P0216
2478857 rs12950376 17 NC_000017.6 25687136 A T CCAGACTACACAAGCACCCTGAGAAATGTGAAACCTCTCCCTTGGCCCCCT 0.8119 LOC388362-[ ]-LOC401876
2478983 rs16965173 17 NC_000017.6 25703114 A G GATATCTGAAAACAATTTGTGAACTATAAAGCATTGTTAAAATAAAAGCCA 0.6963 LOC388362-[ ] LOC401876
2486070 rs8077653 17 NC_000017.6 62482336 T G GCCCCCTTTCTGCCTTTGACCCTCATGGTGGCTTTGAGCAGGCATCTGAAT 0.3286 GH1, GH2, CSHL1, CSH1 [CD79B]
SCN4A
2488104 rs1558875 17 NC_000017.6 66941539 T C TTGTTTCCTCCTTGGTCTTCAGTTTTCTCACTTGACAGTTGAGGGGTTGGA 0.4765 SLC16A6-[KIAA1001]-FLJ10055
2488188 rs2909218 17 NC_000017.6 67061669 T C TGTGTCAGTTGGTAAAGAACTGGAACGAAATGTCCTGGTTTGACGTTTTGA 0.7966 KIAA1001, FLJ10055 [ ] PRKAR1A
2490021 rs9907514 17 NC_000017.6 69328342 G A AATCAAATCCATTTGCATGCCGCTAGTATTCTGTGGATTCTTATTATAACT 0.4729 LOC401887-[ ]-LOC124685
2492846 rs9912666 17 NC_000017.6 71624666 G A ACATTACTTTAAGAAAGAAATCACCGATCAGTTCCTCTAATGCCTTGTTCT 0.1504 LOC400619-[SLC39A11]-L00390811
2522402 rs727312 4 NC_000004.6 80654964 T C ATTCTGGTCATAAGAAAGGGGAAAATTGAGGCAGATTTTTTCGCCCTACTA 0.4955 PAQR3-[ ]-GK2
2528446 rs955608 4 NC_000004.6 120285975 C A ACCCTGCTCTTTGAAAGTAGGAACCCCATCTTTTCATAGTTCTTGGCATAT 0.126 SEC24D-[SYNPO2]-MYOZ2
2563109 rs711239 2 NC_000002.6 30603678 G A TCCTTCCACTTCTTCATCAATGACCGGCACCTGCAGGGTGTGAGTCACTGG 0.7625 LOC285043-[ ] UNQ1849
2583974 rs1018139 4 NC_000004.6 167425628 G A TTCCTGGTTTGTGCAGTTCAACAACGGTGGTTTTGGACTGTATCTACTTGT 0.8993 LOC391715-[TLL1]-SPOCK3
2596560 rs661197 15 NC_000015.5 37812546 T C AACTTGCTGACTTAGTACCATGAAATGAATAGCTATGAAGGAAGTGAGAGA 0.9881 FLJ35989 [GPR]-LOC388113
2603232 rs256846 5 NC_000005.5 155899663 T C TAAATTCTTACCAAACTATGCCCAACATGTTTTCATTTCATTAAGCAGTTA 0.2038 LOC389340-[SGCD]-LOC153743
2606259 rs245592 5 NC_000005.5 162095447 C T TAAAGCAATATTTTGCTAGTGCTAGCGTGTGTCCAAATGGAATTCTTTCCC 0.7624 GABRG2-[ ]-MRP63P6
2634363 rs1035191 4 NC_000004.6 88135652 T G GTATCCCAATTCCTGAACGGTGGGTTATTAAATCTGAAACTTGAAGGAGGA 0.7175 MAPK10-[PTPN13]-SOAT
2641152 rs689695 15 NC_000015.5 45068922 A C TAAGATTTCACTTTGGTTAGTTAACACTTGAAAGTAAATACTCAGATACTA 0.6289 LOC145660-[ ]-SEMA6D
2677683 rs421628 4 NC_000004.6 86748728 G A CCTATTTTCTTGTTGTTGACAAGAAAGAAACATACAGCGTTTCAATGACAG 0.4741 LOC391675-[ ]-DKFZP564B1162
2678537 rs1564138 4 NC_000004.6 22202664 T C AAATAAATACATAAATAAATAAAACTAAGAGGGAGTTGAGAATGACCAGAA 0.1207 FLJ30194-[GPR125]-GBA3
2684490 rs1345439 16 NC_000016.5 48528973 G A TTTTCTGCCAATGACTTTCTTCACCATCTCTTTCCTGTGTCTCATTTGGCA 0.3209 N4BP1-[LOC388273]-CBLN1
2685247 rs1346075 4 NC_000004.6 68032302 T G GCATGGAGAATATTGGTCATATTTGTTTACAGCATGTGTGACTTAATAAAT 0.4612 EPHA5-[ ]-CENPC1
2734519 rs1403724 3 NC_000003.6 150338303 T G GCTTTTCTTCAAACATTTACTAGATTCTTATTTGTCAAATCTTTATGTGTG 0.7577 LOC389-160-[ ] LOC116441
2745240 rs1417712 9 NC_000009.6 106975923 T C ATCCAATCCCTTCCCACCCGCATGATGACACTTTGCCAGAACTGGCAGCAA 0.8561 LOC347292-[ ] IKBKAP,
ACTL7B, ACTL7A
2751104 rs1424148 16 NC_000016.5 76976393 C G ACTAAGTCAGGTGGGTAACACAGCAGTGAGGGCTGAGATCTTGCAGCTTAG 0.1855 CASPR4-[ ] HSRG1, LOC400547
2783077 rs1460969 5 NC_000005.5 7818388 G A CAAATGATATAACGGCAGAAATACCGTATCTCGTATCTCTATTGACTGTGA 0.5676 LOC401174-[ADCY2]-LOC134121
2790279 rs1484274 5 NC_000005.5 154838009 A G GGGAAAAATTAAGATGTTGGCCACAATTGCTATTAATTTGGCCTGAGCTGC 0.5234 LOC402234-[ ]-LOC389340
2814609 rs349506 3 NC_000003.6 141542451 G T GGAGCTGGCCTTGGAAAGCTGATTGGTCGGGAGAAGTGGAAGAAGGAGATG 0.8862 NMNAT3-[CLSTN2]-TRIM42
2863248 rs533159 4 NC_000004.6 130600270 A T AAGTCCCTGAGATTAAGAACACGGCAGAGGATTTGTGACTCTACTTGTGTT 0.3094 LOC391697-[ ]-LOC391698
2899607 rs1927923 9 NC_000009.6 115938436 A G AGATGAGATCAAGTAAAATCTCCTTAGAAGCAGAATGGTTGATCAAATGTA 0.8332 TLR4-[ ]-LOC340477
2926674 rs2045812 4 NC_000004.6 22294777 A G GACTATTTATGTGCTGTTTGCTAAGACAGTTCCTGAGTAGAACCCTGTCCC 0.6426 GPR125 [ ]-GBA3
2931858 rs2054397 3 NC_000003.6 179583353 G A ACTAAATAGGGAAAATGTCAGCTGAGTCCCACATGTAGATTCCTTGTCATC 0.5908 LOC401101-[KCNMB2]-WIG1
2933057 rs2056044 4 NC_000004.6 184201330 A G TCTTGCTGATGGGAACTATGACAACATGACATTGAAGAATTATGAGCTAAA 0.6058 LOC90768-[ ]-ODZ3
2946402 rs2114438 15 NC_000015.5 46415985 T C CCATTTTAGATTTATTAGCAGTTAGTTGAAACAACAGATTTTGTGATTTTT 0.2849 DUT-[ ] FBN1
2946891 rs2115828 15 NC_000015.5 52183171 A G TTCACAATCTTTGAATTTAAACTCAATCGGAAGGAACCTCACATGAGATTA 0.9817 LOC400376-[UNC13C]-C15orf15
2977230 rs171649 5 NC_000005.5 67585630 G A GAGCTGTGTTTTGCATACATGGTCTGTGGTCTGTTTTGTGTCCTAGGTCTG 0.6097 EF1B3-[PIK3R1]-SLC30A5
2993728 rs1295241 5 NC_000005.5 154920028 C G AAGTGAATTTTACTTTCTCCATGAAGCTTTCTAATCTCACAGAGTTACCCC 0.4173 LOC402234-[ ]-LOC389340
2997317 rs2202308 4 NC_000004.6 29577072 A G AAATGTATGTGGTCATTAGGTTTTCAGCATTATTCAGTCATCCCCTCTTTT 0.8236 LOC391643-[ ]-PCDH7
3106665 rs393973 5 NC_000005.5 813578 C G ACAGCATTTTACACCCCTAGCGTAACTGTGATTCAGATGAGGATTGCAACA 0.6161 LOC401167 [ ] ZDHHC11, LOC389261
3107121 rs13171870 5 NC_000005.5 1948745 G A AACCGAGGACACAGACGCAGGGCTCGGGCAGAGTTCCCACGGTGGGCACAG 0.5691 LOC389267, IRX4 [ ]-IRX2
3111057 rs2713575 3 NC_000003.6 129615264 A G CACAAGCTCATCATCTATTCGAGTCGAGAGTATTCAGTTATCAGCCTCAGA 0.4955 LOC391572 [GR6] RPN1, FLJ40473
3112389 rs10512737 5 NC_000005.5 40455544 G A TAAATTCCTAGTGCCTTCGAGTAAAGCTGTTCATGGAGCATATTTAAGACA 0.8709 LOC285634-[LOC389285]-PTGER4
3114067 rs6802103 3 NC_000003.6 131858889 T C CTTCTTGTGGTCATGTGAGACTCATTCCTTTTACTGTTTCTGTGCATACCT 0.2047 PIK3R4-[ ] GSTO3P1
3115306 rs35097472 5 NC_000005.5 6135712 G A TCTCCAGTTGTTTCTTTTGTGTGAAGTAACTTCCAGAATCCATGACTCACA 0.7383 K1AA0947-[ ]-LOC401172
3115452 rs4438885 5 NC_000005.5 43466591 A C TTTACTTGATTCTCCCAGTTGCTGGATATTTAGGTAGTTTGATTTTGTCTC 0.9812 CCL28 [ ] FLJ21657
3117549 rs4854582 3 NC_000003.6 134393392 G A TCTGTCTCAACTCTATATCACCTGTATGCTTGTAGACTGGCAAAGAAAGTC 0.1181 NPHP3-[MGC3040] BFSP2
3117608 rs1201674 3 NC_000003.6 134405511 T C CTCAACTCAGAGTCAGGGTTTGAACTATATCCCCGGCTGGAATGGGGGCCA 0.8833 NPHP3-[MGC3040] BFSP2
3118276 rs10475362 5 NC_000005.5 7331686 C T TCTCCAAACAAAACCTCTCTCTTTCCGACTCTCCACCCTATGCTTTTCCAA 0.3987 POLS-[ ] LOC401174
3118987 rs13189538 5 NC_000005.5 7838724 G A AATTCTCCCAACTTTGTTATTGGTCGTTGAGATGATACACATTCAGTACCA 0.5736 LOC401174-[ADCY2] LOC134121
3122355 rs34286321 3 NC_000003.6 138173434 G T TACCTAGAAACTCCTTTAAATTTGGGTTTCTGAGAGTAGTAATGACTTGTA 0.8018 MGC34923-[ ]-NPM1P17
3122754 rs7647718 3 NC_000003.6 138188222 A G TGTTTTTGGAGGGCAGAGATAAACTATGGAAAGATGGAATGCTGTATTTTT 0.7963 MGC34923-[ ]-NPM1P17
3123186 rs6881925 5 NC_000005.5 53710002 T C CAAAGCACATGTGAGGCCCAGAAGGTGGTTTTTCATGCCTTTAATAACCAT 0.3979 ARFRP2-[ ]-HSPB3
3125188 rs439893 5 NC_000005.5 11335191 T C CGAGTTTTTAAGTGCCCAGAGAAGATGTACTCAACAGGGAGAGTTAAGAGG 0.621 DAP-[CTNND2]-LOC401175
3127128 rs26269 5 NC_000005.5 14182336 T A GGTTTCCAGCTATCATCCCTGTTTTACCTCTTCTTATTCCTGGGTTTGAGA 0.522 DNAH5-[ ] TRIO
3134325 rs2769187 9 NC_000009.6 116309722 A G TAAATTAAAGCATGAACTACGAGGAACCTGTATCTAAGTAAAGGGACTGAC 0.5203 LOC389787-[ ]-LOC347165
3134356 rs2769192 9 NC_000009.6 116321490 A G GATGATGGTCATATAATTAAGTTTGACATCTTTACTGGAGAGCACATCAGT 0.5378 LOC389787-[ ]-LOC347165
3134360 rs2806065 9 NC_000009.6 116326118 G T CACATTCTTTGTATCTATAACACATGCTTCTGAAATATCAGATACCCATCA 0.5298 LOC389787-[ ]-LOC347165
3141936 rs7340627 3 NC_000003.6 158153306 A G CTCATTAGAAAGGACTTTGATGCACATTTTTATGCAAGAGGTGAATTCTTC 0.6012 LOC339892-[LOC339894]
LOC391589, CCNL1
3142103 rs16827384 3 NC_000003.6 158306837 A C TGGAGCATTCTTAAAGCTAGTAATGATCTTTGCAAATTTAAATTTTCCATA 0.6842 LOC391589-[FLJ12604]-PTX3
3150971 rs7618373 3 NC_000003.6 177657932 G A GATAAGAGAGTAAAGGTAAGCTTTCGGGGCCCTTTTTCCACATGTCATATT 0.6275 LOC254827-[ ]-IRA1
3151597 rs16829750 3 NC_000003.6 179599636 G A ACCACCCTATACCATCTCCTTAGGCGCAGCACTGTTTTGCTTCAGATGCTT 0.5934 LOC401101-[KCNMB2]-WIG1
3151603 rs16829771 3 NC_000003.6 179605903 T C TAATCTGAGTTTCTGAATGTACATGTAGATGAGAGTACACATGTGTGAGAG 0.5965 LOC401101-[KCNMB2]-WIG1
3152573 rs17188103 3 NC_000003.6 183065384 A T AAACAGAGAAGTCAATGGCAAGTTGAATTTTGTATGGTGACTTTACCAGAA 0.8419 LOC401102 [ ]-LOC401103
3152805 rs1357451 3 NC_000003.6 183806996 G A TGATATTTCAAAGTTGTTTTCGCTCACATTCCTTTCATTACTGTCAAGAAT 0.2736 LOC402152-[ ] ATP11B
3170195 rs11661897 18 NC_000018.5 69672542 C T TGGGAAGAAGATCCAAACCACATCACCAGGATTCAGTTAACCATCCCCCTC 0.3085 LOC400655-[ ]-FBXO15
3174413 rs12189352 5 NC_000005.5 79619174 A C TGAGACTTTCTCTGGCTGGCTGCCAACCAAAGACTTCCCACAATGGTTCTA 0.5628 THBS4-[C5orf12] LOC391803
3174758 rs10514187 18 NC_000018.5 71635777 A G GGCTTGATCCTCTAATGACCCATGGACTTGAATTAGAACATCATCCTGGAT 0.953 LOC284274-[ ]-LOC284275
3181874 rs601499 5 NC_000005.5 88136760 A C GCAAAGACTTCAGGGCCAGGCTCCAACTTTTACAAACACTCAAGATAGGAA 0.4167 MGC33214-[MEF2C]-CETN3
3187067 rs6879703 5 NC_000005.5 92529821 G A ACTAACGCTGACAAGAGCAGACATCGTACAAGTGGGACAGGGGAAAAAAAT 0.8922 LOC391810-[ ]-LOC391811
3191406 rs11149997 16 NC_000016.5 77329233 A G ATGTTGCATTTCAGATTTTTTTGAAAAAAAGCCAGAGCCCCAACAATTTAA 0.3284 ADAMTS18-[ ]-LOC388299
3193146 rs9928690 16 NC_000016.5 78378382 A G GAAATCCTCCTTCCTTTTTAACAAGACAAGTAGAAAACGAAAACAACATCA 0.6059 LOC342419-[WWOX]-LOC401862
3194833 rs441333 16 NC_000016.5 79406333 A G TGCAAATCAGCAAAGTGAAGCTGGTAAATCTCACTTCCTATTCCCTCTTAG 0.5697 WWOX-[ ] MAF
3200432 rs16957764 16 NC_000016.5 82393722 C T GCCACACACAAGCCTATTCTAAACCCGTCTTTCTTCCTTAAGTGTGCCAAT 0.913 MPHOSPH6-[ ] CDH13
3222073 rs13032210 2 NC_000002.6 147102514 G A GTCAGATGTAGATACGTTTTTGAAGGACTGAAAACTAAATAATTCCATTTC 0.985 LOC402107-[ ]-LOC200583
3255514 rs4679045 3 NC_000003.6 33515931 G C TCTTATCCATGAAATATTTTTGAATGAATTATCTGAATGAATATGCACATT 0.6151 UBP1-[CLASP2]-PDCD6IP
3263451 rs12053901 3 NC_000003.6 111773106 G A CAGATTGGCTTCATTCTTTAATTTCGATATGGACTCACTTACAAATGGACC 0.9721 LOC389141-[ ]-LOC151760
3263776 rs16860850 3 NC_000003.6 114372525 G A TATATTAGTTTGTGAGCATTGAGTTGCCTAGAAAAGTTTGGAAGTCCTACA 0.8123 BOC [ ] LOC402136, FLJ11142
3271579 rs6708711 2 NC_000002.6 114619662 A G GGAAAAAAAAAAGACTGAGGCCGTGATATGTGTAACATGTTATTAGATATG 0.7258 bA395L14.13-[SLC35F5]-ACTR3
3287599 rs7218003 17 NC_000017.6 49047130 T G TTCTTGACTGTTGGTGAGGGAGTTGTATCAACCCCAGGTTCTTAAACTTGT 0.3988 CHAD, FLJ11164, FLJ20920,
MRPS21P9 [ ] EPN3, MYCBPAP
3288070 rs2215290 17 NC_000017.6 49698859 C T ATCAAACTCAGTCTTCTGACTGGCTCCTTTGGTCTTCCCTATTTCTCTTAA 0.8634 SPAG9 [ ] NME1, NME2, MBTD1
3288843 rs6504747 17 NC_000017.6 50332654 C T ACAAATGCAAGAGTAGAAGTACACACGGAGCAGTGGCAACTCAAGAGAGAA 0.962 LOC388401-[CA10]-LOC339209
3288850 rs16950512 17 NC_000017.6 50341788 A G AACTCATTTTCCATTTTCCATGCATAGGATAGTAGGTCCACCTCACCTTTA 0.931 LOC388401-[CA10]-LOC339209
3290010 rs4501302 5 NC_000005.5 65974935 A G CCCACCTCAGTGCATGTGTGTATACATGGATTGTTTTAGTATCTTAATCAC 0.7552 LOC202227-[LOC375449]-KIAA0303
3293153 rs6870517 5 NC_000005.5 67829547 T G TTGTGACTGTCACCGGGAGACAGAATAAGTGAGGTGGCACAGGTGCAGTAT 0.4793 PIK3R1-[ ]-SLC30A5
3296481 rs4794717 17 NC_000017.6 55839242 A C GAGTGTGGGAAATTAGTGCAGGCCCAAGGAAAGGAAGTGTGAAACTGCTTC 0.1752 FLJ11710 [MSI2]-MRPS23
3303532 rs33934033 5 NC_000005.5 96316939 G A GTGTGGACTTTTACTGTTGAGCTAAGGTTTATGTTTATATATGTTTTATTC 0.4718 ARTS-1-[LRAP] LNPEP, FLJ39485
3318048 rs6872948 5 NC_000005.5 135601773 T C GCTGCTTCACGCCTATAGCTCAGTTTTACAAATAGCTATAGTTTGGACGCT 0.4334 MADH5 [ ] TRPC7, LOC389332
3322140 rs13155464 5 NC_000005.5 142965137 T C AGCTAGAACTCAAATCTGGCCTTGGTATGCAATCTTGACTATTTTAAGCTC 0.872 LOC389335-[ ]-LOC345537
3325587 rs7732327 5 NC_000005.5 146853063 C T ATAACTCTAATGACTTTGTAGTTTACGTGCAAAGGCAGAAAGAGACCTCAA 0.4176 MGC22688-[DPYSL3]-KIAA0555
3326948 rs17778143 5 NC_000005.5 148206881 T C AAGTGGCAACGAAATAAATGGTGTATGGACCTAAAGTTGTTAATAACTCAA 0.7801 HTR4-[ ] ADRB2
3328007 rs10515637 5 NC_000005.5 149270111 A G CTACATT1GCAGCTGCCCATTTAGAATCAACCCACGCTGCCCAGAGCAGAG 0.6198 PPARGC1B [PDE6A]-SLC26A2
3329421 rs9688110 5 NC_000005.5 150992312 G A GGGCATACCAGGGCTGTGGAAAACCGACACCTCAATGATTCCCTTTACCCT 0.6614 FAT2 [ ]-SPARC
3332880 rs12523643 5 NC_000005.5 154831079 T G CAGAAAAAATTTAGTGCTGTGGGAGTCATCATGATATCCCGGAAAGGCACA 0.5465 LOC402234-[ ]-LOC389340
3339124 rs2431271 5 NC_000005.5 162097173 T G TAAGTAAACATTAAATGCTCATGAGGAAATATTTTACACCCAAATATTAAT 0.7735 GABRG2-[ ]-MRP63P6
3352050 rs2014379 X NC_000023.5 105103239 C T TGTAGGAAATTGGATGTTACTATTCCTTCAATTCGGGGCTTCTAATGGGTA 0.8144 ZCWCC2-[FLJ11016] FLJ20130
3373581 rs17597288 18 NC_000018.5 51326195 A G AATGCCTGGGAAAATGATCTAAAGCAATAATCCTAAGAAATAACCAAGAGA 0.8768 SE57-1-[TCF4]-TXNL
3386350 rs17648108 5 NC_000005.5 177945157 T C GAAAATTTGAGGGAAATACAGCTGATTCCTTATGGTGAACCTGGCCCAGCC 0.7125 MRPL50P3-[COL23A1]-CLK4
3395544 rs4380588 4 NC_000004.6 6324430 G A GCCATCTCTCCTCCAGGCTGGAGTCGGTGCTTCCCACAGTTACTTCTCACG 0.763 LOC285484, LOC389198 [ ] WFS1
3396622 rs17178920 4 NC_000004.6 8276158 C T CAGCAGCAACTGGGACGGAGCAGGGCCCACTGAGTCAACCACCCAGGTGTG 0.8043 LOC389199-[ABLIM2]-LOC391618
3396741 rs2280569 4 NC_000004.6 8559677 C T TCATAGACAAAACACATGTAACCCACGAAGAGTTTGTTTAAACCCAAGGAA 0.782 HTRA3-[ ] ACOX3
301101 rs10006709 4 NC_000004.6 17257440 T C ACCCCAATCCAAAAATCCCTTTAACTGCAACTCTGAAAAAAATGCCAACGA 0.9783 LOC402173-[QDPR] LOC391639
3404095 rs11933465 4 NC_000004.6 22227454 A G AAATGTAAATGGAGCATACCTCTGGATCAGAAGATTTTAGGTATTATTATT 0.4132 FLJ30194-[GPR125]-GBA3
3412405 rs6829422 4 NC_000004.6 100204996 G A CTTGGTAGAAAATCTGGAAGCACTCGTCGCAAATGCCTTTACAACACTATG 0.1709 LOC132556-[ ]-EIF4E
3414039 rs10516493 4 NC_000004.6 103743038 A T GGCACAGCCTTGATGAACCTTACAAACTGCTCTCAGTGAGTGGTTCTCATC 0.689 SLC39A8 [ ]-NFKB1
3417519 rs11098185 4 NC_000004.6 114427028 T C GAACATTAACAGCATCTCTCTCCTATAGATCCAGTTACGACAAAGGTTTTC 0.2821 LOC391689-[ ] ANK2
3419155 rs7675219 4 NC_000004.6 118148630 A C CATAATTCTCAAGGACTTTTATTTAATAGGACTGGAGAGGGATCTGGACAT 0.7392 LOC344978-[ ]-TRAM1L1
3430918 rs12643790 4 NC_000004.6 91232542 C G CCACTTCTATATTCTCTTCTTCCTTCATTTTTCAAATGTTTGCATTTAAAA 0.9756 SNCA [ ] MMRN
3434449 rs6824100 4 NC_000004.6 94964127 G T CTTTTTGTAAGAGGATACAATAAAAGTATGAGTCAAAGAATATATTGGGGA 0.3755 LOC133083-[GRID2]-ATOH1
3435351 rs9942167 4 NC_000004.6 96081870 T A GAGGAGTCAGTTATCTCGGCGACTCTATTTCCTTTTCTGAATATACGATCA 0.6103 LIM [ ]-BMPR1B
3443855 rs11733446 4 NC_000004.6 23339715 T C CTCCAGGATCACTGTGATGATAGGTTCAGAATTCCTCCCTTCAATGCAACT 0.6236 GBA3-[ ]-PPARGC1A
3444361 rs12510610 4 NC_000004.6 42420247 T A ATCAACACCATCCCTTCTGCAGTCATTTCTTCACCATCCCTTCCACGCATG 0.8414 LOC389206-[ATP8A1]-LOC389207
3444374 rs10517038 4 NC_000004.6 42426784 C T AAAGGCCATATAGAAGACAAAAATACCAACTGTATCTATCTCTTACATGAA 0.8449 LOC389206-[ATP8A1]-LOC389207
3447488 s2348813 4 NC_000004.6 45016728 T G GGACTTTTAGCTTTTGAAATACAGGTTTTFTTTTTGGTAATCACATTAGAA 0.6621 GNPDA2-[ ]-LOC391648
3447858 rs17669701 4 NC_000004.6 27515699 G A ATAACAAAATTGTAAGTGTTACTACGGAAAATTCCTTTTTACTACTCTTAG 0.6594 LOC391642-[ ]-LOC285509
3448879 rs7662149 4 NC_000004.6 28897386 C T GAAATTACCATATCTCTGTCTTCTTCGCTGAGTCATGGAATCCCTTCAAAA 0.7563 LOC391643-[ ]-PCDH7
3449937 rs17737935 4 NC_000004.6 29650714 T C TAATGGCCTGGGAGAGAGAAATACTTTGGACTTAAGCATTATGGTGTGTAG 0.8361 LOC391643-[ ]-PCDH7
3452760 rs3113584 4 NC_000004.6 33136093 A G TATTTTTCTGAGCGACAAAATGTAGGAGGCATCATAAAATATGAGGAATGG 0.7918 LOC402174-[ ] LOC133185
3460224 rs16994357 4 NC_000004.6 38141804 C T AGGTGGGTAGGACAGATGTCACCCTCTTTCAGGCAGGAATCTGAGAGGCTG 0.9741 TBC1D1-[ ]-FLJ13197
3475688 rs13111373 4 NC_000004.6 153691353 G C TGCGTATGATCTCAATACTAAGAAAGATCAGAACTGCTTATACGTTACAGT 0.608 LOC389232-[ ]-LOC389233
3477251 rs17032828 4 NC_000004.6 156835329 C T TACGTAGGAAAATATCTATGTTACACGATCTTGTGCAGTCACTGCTATTAA 0.9123 LOC389237 [ ] FLJ21159
3477963 rs10049936 4 NC_000004.6 157875784 T A TCACAGAGACTTGCAGAAAAGAGATTAAATTTACCATAGGATATCCTTAGT 0.8351 FTHP2-[ ]-PDGFC
3480149 rs17332185 4 NC_000004.6 161878565 G A GCTGAACATTATTGTTCCTGAGACTGACTTCTTAGCCATTTATTTTACTTC 0.6901 PDZGEF1-[ ]- DKFZp566D234
3481741 rs17460297 4 NC_000004.6 163608108 G A GGACTTGTACAACCCAGGATTCCTAGTCATTCCTGTCAAACATACACTTTC 0.8208 PDZGEF1-[DKFZp566D234]-LOC92345
3484509 rs13340246 4 NC_000004.6 167062794 C T GCTTTGGGAATAGGGCTTACCAAAACTGGGGCATTTGGTAGGGATGTGGTA 0.7445 LOC402191 [ ]-LOC391715
3485444 rs7657081 4 NC_000004.6 167751275 G A CCATCAGGATGCAATACATAAGCAAGTGAACCCACCCATAATTACTTAATA 0.0064 TLL1-[ ]-SPOCK3
3486976 rs13119904 4 NC_000004.6 66685700 A G TTCATCTCCTGTCATCTCATCTTGTATTCTCACTGAACCTGTATGTTTAAA 0.6912 EPHA5-[ ]-CENPC1
3509817 rs10415223 19 NC_000019.6 61733990 C T GTTTTGTCCTGCTGAATTGGCAGAGCAGTCCCAAAAGAACTGTAACTAAGG 0.5385 ZNF471, MGC9913 [ ] ZFP28,
LOC388566
3510699 rs10417951 19 NC_000019.6 33967121 G A AATCACTGCCAACAGTGGTGCCTGCGTTTGCAAGGGCAGAGGGGCTCTCAG 0.8897 LOC388526-[ ]-LOC148145
3511990 rs879523 19 NC_000019.6 61229262 A C AGCAGAGCTATTTTGTAGATTGTTAAGAAGCTTTTGAGGCCTTTAAAGTAG 0.5949 NALP8 [NALP5]-LOC126208
3512057 rs10518285 19 NC_000019.6 36695508 T C CTAGGCAGAGGTTGTTCTTTCTCGATAGCTGTTCCAAGAGTGCTATCCTGG 0.4946 LOC388529-[ ]-LOC339316
3522226 rs13101469 4 NC_000004.6 125280554 A T TATTTTAAGTTTTTTTGTCTGATGGACTTCTGAGCTCTGCTGTCTGTCAAT 0.806 LOC402186-[ ]-LOC391694
3522237 rs17492375 4 NC_000004.6 125271718 T C TGCAGTCGGTGTGTAATTAAGAGGATGTAATTAAGGATTATTGCTGGATGT 0.8134 LOC402186-[ ]-LOC391694
3524022 rs17339087 4 NC_000004.6 121861556 C A CAGAATTAACGTGCTTCCAAACTGACAGCACCCATTAACAACTCACTCACA 0.5696 LOC344988-[ ]-PRDM5
3526374 rs6659997 1 NC_000001.5 89739285 C T GGACAGTTCAAATGATTCTGGGTCTCATAATTGCTACATGATGTAAGGTGA 0.7088 AD158-[ ] LRRC5
3528443 rs11352973 4 NC_000004.6 128380774 C A TTAAGGCTCCATTCAATCAAAAAAACATTTCATATCATCAATACCACTGTT 0.7653 LOC132817-[ ]-PDZK6
3530702 rs12502992 4 NC_000004.6 131910186 G A ATGGTACCAGAAGACATGCTAGAGGGGATTGGAATAGGTGTGGAGAGCCAA 0.7046 HCP14-[ ]-LOC401155
3531432 rs1705709 4 NC_000004.6 132915159 A G CTGTGCTGAATGCCAGGTAATTGTAACCAAACTCAGGTTCAACTGCTCACT 0.7843 HCP14-[ ]-LOC401155
3531816 rs17049070 4 NC_000004.6 133667612 A G GATGTGTAAAACGTACGTGCCTAAGATCAATGACTGTGTCATCACAGAAGA 0.8554 LOC401155-[ ]-LOC402188
3548055 rs12439488 15 NC_000015.5 39610631 G A AGACCCTTCTCTGGCCTTTTCACTAGAATACAACAAAGATTAAATCAGCTT 0.8662 TYRO3, LOC283747 [ ]-MGA
3554315 rs12904774 15 NC_000015.5 55573969 C T GCAGAGTTTTCACGAACAATGAAAACGCCTGGGAGTGTTCATTGCCAGTTA 0.6293 FLJ14957 [ ] FLJ30973
3554904 rs4775005 15 NC_000015.5 55924221 G A GTGTAATCCTGTCTCAACATCTTGCGTAAGAACTCATTCTAGGAAAAAGAT 0.4236 GRINL1A-[ ] ALDH1A2
3556069 rs34458502 15 NC_000015.5 56413166 G A GGTCTGTGGCCAAAGGCATATCCCAGTCACATGACCACTCCAGCAGCAAGG 0.9825 LOC145780-[ ] LIPC,
LOC400377
3557017 rs11634045 15 NC_000015.5 71216435 A G AGCAAAGAAGTTTGTGCCATTTCAAATAAGTGACATGTCAGACATGGAGTC 0.6667 ADP-GK-[NEO1]-LOC388134
3560562 rs11853481 15 NC_000015.5 45160455 G A GCACAAAAATGCCTCAAAAAGTGTCGTAGCCTATATAGACCATATGATCTC 0.6728 LOC145660-[ ]-SEMA6D
3561023 rs16959379 15 NC_000015.5 45394399 G A GTTTTGATGCCATTAGGTTCAAGGGGCTCAACATCTGGTAGAAGAGATAAA 0.9003 LOC145660-[ ]-SEMA6D
3562810 rs2678425 15 NC_000015.5 60240216 A G AAGAGCTTGGAACAAAATTGCCACTGGGGACCATAAGACTAACTGCTGCGC 0.6898 LOC255177 [ ] FLJ38723
3563460 rs12916536 15 NC_000015.5 46422627 A G AAGACTGCTACATTAATAATTTGGTATAAGTGTGGATGTGTGTGGGGGTGT 0.2404 DUT-[FBN1]-LOC400370
3563481 rs9920570 15 NC_000015.5 46431504 A G CAACCACTATGCCCTCACCATCTGCACAACTGCTTTGGAGCTGCAGATCAG 0.2485 DUT-[FBN1]-LOC400370
3563492 rs8034591 15 NC_000015.5 46440824 C T ATCTCTTCATATTGGGTTTTTTGAACGTGGGGAAATGTCTTITTCTTTCTA 0.3002 DUT-[FBN1]-LOC400370
3563516 rs10519174 15 NC_000015.5 46450680 G A AACTAACGATATCATAGAAGATGACGCTCCTGATTTGTGGGTTAATCTTTC 0.3027 DUT-[FBN1]-LOC400370
3563548 rs2555470 15 NC_000015.5 46463496 T C TAGTTATCTCAATATCCACAGAATGCTACCCTGACAGCAAAATGCCTTGCA 0.7572 DUT-[FBN1]-LOC400370
3563568 rs4774517 15 NC_000015.5 46475347 G T GGGTGACAACTAGTGGAGTCCTAATGTGCACCAGGTGTGCTCTTTGTACCA 0.7584 DUT-[FBN1]-LOC400370
3563628 rs11070644 15 NC_000015.5 46500553 T C GAAACTACAGTTGCTGCTTACTATTTGAAAGACTGTCAAAGGAGTGGCCAT 0.7604 DUT-[FBN1]-LOC400370
3565071 rs12900106 15 NC_000015.5 61731727 G T TGGTCTTGTATAACAAAAAACCAACGCGTTCAAAATGGAATGATATCCTCT 0.1262 LOC400380-[HERC1]-DAPK2
3565203 rs9972404 15 NC_000015.5 61658726 G A CTCAACAATTACTGATAACCAAATTGGCATAAGAAACTTACTTGCAGTTAA 0.1246 LOC400380-[HERC1]-DAPK2
3565214 rs2228511 15 NC_000015.5 61669846 C T TGCAGGTGCCACATAACAGGTAGTACGGATTTCCACTCCCACATTCACCGC 0.1251 LOC400380-[HERC1]-DAPK2
3565239 rs12906986 15 NC_000015.5 61683798 T C ACAAAATGTAATAAAAAGCTTTTGCTGGTATAAAGTTTTGTTGTTCTAACC 0.1185 LOC400380-[HERC1]-DAPK2
3565269 rs4984318 15 NC_000015.5 61800500 C T AACCCTATCAGCAAAGCAGAATGAACGTGTGCTTCCAGGAGTTTGGAGTAT 0.1324 LOC400380-[HERC1]-DAPK2
3565281 rs6494436 15 NC_000015.5 61807121 C T GTTAACTTCAAATCAGTCAATGACACGGAGTTGTTCAACAAAATTATAAAC 0.1291 LOC400380-[HERC1]-DAPK2
3565292 rs10152453 15 NC_000015.5 61814430 C A CCCTACGCTCACCAACACAGATTTACTCACTTCCTCCTCTAACTCTCTTAC 0.1293 LOC400380-[HERC1]-DAPK2
3567213 rs11637964 15 NC_000015.5 62957552 A C TATACAATTTGTGCATCATGGTACCACAACGATGAAAGTCAATTCTTTCTC 0.9034 pp9099-[LOC348094] ACP33
3567949 rs3784308 15 NC_000015.5 49243454 A G TAGTCACTTAAATTTGGCTGACTAGAGCCTAATAGACCAGGAGAATTAAAA 0.9481 LOC388121-[CYP19A1]-FLJ11181
3592740 rs26320 5 NC_000005.5 115824481 A G CATCTCTATGATTTTTGTTATTACAGTAGGTCACTGAGCTGTTATTTATTT 0.5314 COMMD10-[ ] SEMA6A
3592834 [NULL] 5 NC_000005.5 115854548 G C AGGGAGCTTCATCAGTACTTTGTTCGTACCTCCAAATGGCAACTACAAGGG 0.8375 COMMD10-[ ] SEMA6A
3594277 rs2602234 4 NC_000004.6 141114754 A G CTTTAAATCAATTGAATTAGGGTTAGTGTGATCCCCAGATCATGAGGAAGC 0.6336 SET7-[ ] MGST2
3596962 rs3909595 4 NC_000004.6 142454652 G A ATTCCAACATAGTTTAAATATCAATGTGCAATGCGTGCAAAAGAAATCAAA 0.7105 KIAA0882-[RNF150]-LOC389227
3605475 rs7686137 4 NC_000004.6 147784092 T C GGCAGGAAGCAGGGAGCTCTAAGGGTCTAAAGAATCAGAGTGAAAACAGGA 0.2941 LOC345051-[ ]-DKFZP566M114
3609443 rs6866678 5 NC_000005.5 126844177 A G TTCACCGGAAATGGTGTACCAATTAACAACATTCACATTATAGTTTGGGAC 0.1961 LOC345818-[MEGF10]-LOC389322
3611749 rs17026183 4 NC_000004.6 150882380 T C AAGACTAGATCTTTTTGGTAAACTGCCTACTGAAGGGATCAGCTAAGGTCC 0.452 LOC389231-[ ] LOC285423
3612255 rs2683090 15 NC_000015.5 33824979 A G CCAGTAACTTTTAAAATGGAGGCGGAATTAATAACAGCAGCAACAACCACA 0.2717 MGC14798-[ ]-HH114
3613803 rs33985535 2 NC_000002.6 11325911 C T GCAGGTGTTCACTTGCGACCCTTTTCGTCCCTTCCAAATCCGGCAGGTTCT 0.5104 FLJ25143, FLJ33534 [C2orf22]
ROCK2
3614176 rs7668154 4 NC_000004.6 152644037 A G AATGCTTTATTGACATTATACGACTATGCTAAGAACTGTCAGGCCTCTGAG 0.0458 RPS3A, U736 [DKFZp434D0215]-
ESSPL
3614192 rs11099788 4 NC_000004.6 152663075 G A CAGGCATAAATGAAATCAGATGCCCGCAGAGAAAGCTGTGTGATCACTCCA 0.0465 RPS3A-[DKFZp43400215]-ESSPL
3616400 rs8024166 15 NC_000015.5 37731881 T C ACATCCAGGAGCACTCAATATGTGTTGAATCAATTGTTCAAAAACAGAAAT 0.9773 THBS1-[FLJ35989]-GPR
3641695 rs17062188 4 NC_000004.6 177488084 T C AGAACCATTCATCTTCTTAATCCCATGCCTCCTGCTTGGTTTATTTGTATG 0.6739 GPM6A-[ ]-WDR17
3666604 rs4779061 15 NC_000015.5 81173449 T G CACGTCTGTTTTTGTTTTCAGGAATTTCCCGAGTCTGTTGGTATAAAAAGA 0.8355 LOC283693 [LOC123722] KIAA1971
3666695 rs17258343 15 NC_000015.5 79933923 A G TTAACCCTGTTATAGAAAGAATGCAAACAGAAAGAAAAGACTTAATGTAAT 0.8224 TMC3-[ ]-LOC390621
3666917 rs4420497 15 NC_000015.5 82516035 C T TTTCTTCCATCCCTTTGGAAAATGCTGTTTAACCTTAACAATTGATATACC 0.878 LOC388158 [LOC388159] LOC388160
3668870 rs17705887 15 NC_000015.5 85624263 G C GGGGACAGGAATCAAGGCGGGCCCAGGGTCGAGATAGAAGGAGCTATTTGA 0.748 LOC388169-[ ]-FLJ31461
3670712 rs11631508 15 NC_000015.5 86228234 A G GGACACAGAGACGAGTATAAATTCAAAGGTCCTCCCTCCTTTAATAACACA 0.6837 LOC388170-[NTRK3]-MRPL46
3673009 rs12437470 15 NC_000015.5 89304173 G A GTATCCTGACCATTCACAAAGTGTCGTGCCACAGCACTTGCATCATTAGGG 0.8493 PRC1, VPS33B [ ] LOC390638
3674864 rs12443068 15 NC_000015.5 91922674 T C CACGAAGGCTACTTTCTCCGAGAAGCCCTCCTTACCCCCATGTTAAATCAG 0.2732 LOC390641-[ ]-LOC283682
3675147 rs17711781 15 NC_000015.5 92443188 A G TTCCTTCAAACAATCACCAACTCCAGTTTCCTGATTTTAACTCAATTGTCA 0.039 LOC400455-[ ]-FLJ11175
3684385 rs149511 5 NC_000005.5 16522331 T C CAAAAAAAATTACCAAATTGATCACTCTGAAGAATTTAAACTAAGATCACT 0.6809 ZPR9 [ ] FLJ20152
3686058 rs16885644 5 NC_000005.5 19694961 A T GAAGCAAAATATATACAAGTTAAAGATATGTGTTCAGCTTCAGTCCAGTCT 0.9724 LOC391770-[CDH18]-LOC266786
3686735 rs4492078 5 NC_000005.5 21838097 A T ATTTCCCATTTGTACACATGCAATATGATTAAAATAGATCTCTAAAGAAGA 0.7458 MGC22265-[CDH12]-PMCHL1
3686757 rs13153198 5 NC_000005.5 21860993 T C GCTTCACTTTTCTGCCTTTACTTTGCTATTGGAAATTCCTATAATTTGCCT 0.7935 MGC22265-[CDH12]-PMCHL1
3686764 rs6452004 5 NC_000005.5 21869848 G T TTTTCATCATCTCCTTTCCTGGGGTGTTTTCACCTCACCATTGGAGGCAGC 0.8253 MGC22265-[CDH12]-PMCHL1
3687650 rs7726038 5 NC_000005.5 23251375 T G TTTGCGAAGATGTTTCCTATTGCCTTAAATACTTGCCTTGCACAGTAGCTT 0.419 CDH12-[ ]-LOC391771
3687661 rs10038864 5 NC_000005.5 23272263 A T TTGATGGAATTGGAAAGGCAATTTCAGCTCTAAATCACCACAAATCTTCAG 0.4564 CDH12-[ ]-LOC391771
3692953 rs13161116 5 NC_000005.5 33827188 T G ACAGCTGCAGCAGCTGCATATCAGATAATGGAATCTGCTGAGACACTGGGA 0.6889 LOC391776-[ADAMTS12]-SALPR
3693100 rs10077475 5 NC_000005.5 34054510 T C TAGAACCAGAAATGGGTGCCAGAGATATGCCTGCACTAATCTTAAGTGGGG 0.9916 AMACR, AAATP [ ] C1QTNF3
3700031 rs8046048 16 NC_000016.5 25455441 A G GCTCCAGGTGAAAGAACAAAGCCACATGTCCTTTTCTCCACTCACCCCTGA 0.3947 HCP39 [ ] HS3ST4
3707022 s16957821 17 NC_000017.6 9148670 C G GTCTTTAACATGTAACTCGATCTTCCACAGATTAAGTGACAAAGTCATTCA 0.8711 LOC388334-[NTN1]-LOC400572
3708771 rs4785287 16 NC_000016.5 49210946 C A CAGCTCCATGGATGACTGGGAGAGACAGCCCCTTGCAGAGCACCCACACTT 0.8226 LOC400535 [MGC33367]-OAZ
3713131 rs17711876 17 NC_000017.6 15044582 A G TCCCAGTTCCTACAGGTTGTTCCTCAATGATGCCTGGATCTCACTTCAGGG 0.6405 LOC400576-[ ] LOC390765
3713139 rs9914741 17 NC_000017.6 15053614 C T CACCCATATCTGCACTAAGATTTTCCGTAGGACTTTGGGGTCTTGTTTAAT 0.6662 LOC390765 [ ]-LOC388340
3715741 rs7187684 16 NC_000016.5 55573718 T C GATAACGGATAGCGGCTCAGGAGAATATTAAGAGCATCGACTCTGGAGCCA 0.1977 LOC390732 [CESR] CES1
3748654 rs34056793 X NC_000023.5 68207123 T C GTTGGACAGCTTGGCCTCTGATTCATGTAAGCTTAAGAAGGTCTGCTACTA 0.9843 LOC139562-[ ] IGBP1
3751183 rs5936560 X NC_000023.5 68565445 A T TCTGCTCTCCTTGGGCCTTAGTGTCAGCTCTAAAGATTTATAAAGGTTGCA 0.7368 KIF4A, OBDPF [DLG3]-TEX11
3819011 rs34963996 X NC_000023.5 85375129 G C GTACAGTGTACAAACGTCAACAGAAGACAAAGATATGCCTAGAACTATCTA 0.917 DACH2-[ ]-KLHL4
3819892 rs5949613 X NC_000023.5 92463278 C A TGATTGCCGACCCCGTATATTGGTTCGAGGAGCTAGATTTCCTTACTGTTA 0.5697 LOC392503-[ ]-CALM1P1
3819894 rs5949644 X NC_000023.5 92477379 C T GTAAAATGTTTATTTTGCTCTACTACACCAGACTAATTAAACAAATCAGAA 0.5656 LOC392503-[ ]-CALM1P1
3820201 rs5949835 X NC_000023.5 94424720 T C TTATATGAAGCATTGCCCCATCTGCTCAATCCACAGACACACTTGCTTCTT 0.6476 LOC401606-[LOC392504]-DIAPH2
3820225 rs6523008 X NC_000023.5 94480722 A G CCCAGAAAACATTAGTAGTTGCCCCAAGTTATTCAAATACAGTTTTCCTGA 0.641 LOC401606-[LOC392504]-DIAPH2
3842849 rs6610426 X NC_000023.5 39451157 A G CTTAGTGGGTAACATCTTTCAACCCAGGTAAGATTTCTAATTAAGTTTAGA 0.8499 LOC402394-[ ] ATP6AP2
3848797 rs17326689 X NC_000023.5 105624912 G A CTTAAGGGGAGGATAGCTGGGACCCGTCTATTTCCGTGGATCTGGGCACAG 0.898 KIAA1817 [ ] PRPS1
3848852 rs1407901 X NC_000023.5 106045348 G A ATTCTCTGCTCTTGGAGACCTGAAAGGCCAGAGAACTCCAAAAGACAAAAG 0.5627 TEX13B [ ] MGC44287
3857566 rs5952158 X NC_000023.5 114303633 G T ACTAAACAACTGAAATGTTGCACTGGTGACCAATGGGCTGGCTGTCACCAG 0.9717 AGTR2-[ ] SLC6A14
3861184 rs2238902 X NC_000023.5 10621952 T G GCCCTAGAAGGATCTTTTACTTGCTTTCATTTTTCCACAGTCAAGTTATAT 0.741 HCCS-[ARHGAP6]-AMELX
3862078 rs5935311 X NC_000023.5 11739389 T C TTTCCTCTTTCCTTTCTCACACTTATGCAGTTGGTTATAGTTCATCTATTG 0.7273 MSL3L1-[KIAA0316]-PRPS2
3862097 rs7876995 X NC_000023.5 11756116 C G TAACCAGATITCCCATTGACTCCTACGATGAGATTTACATAACTTGATATT 0.7179 MSL3L1-[KIAA0316]-PRPS2
3863206 rs17322192 X NC_000023.5 12779533 C G AATTTATAAAATGGATAGGCAATGCCTACTTGACATGATTGGTGAGGTGAA 0.6033 LOC389839 [ ]-EGFL6
3865731 rs6632799 X NC_000023.5 15669009 G T TTCTATTTACCACTGGACAAAGACCGAGCTAGAGGCAAATCTTGAGAATAA 0.8404 LOC139451-[LOC139452]-LOC392429
3866218 rs12396950 X NC_000023.5 7489538 G T CCCTTCATGGAGGACCTTCAGTTTTGGGGAGCTGACCTGTGCTGACTTAGC 0.5739 DXS1283E-VCX-2r
3868546 rs12833104 X NC_000023.5 112688913 G A CAGCCTTTATCCTCAGAGCAATAACGATGATAGTGACAGTTCTTGACTTTT 0.8004 LOC286528-[HTR2C]-IL13RA2
3870054 rs5956542 X NC_000023.5 121207687 T G GAAAAATGGTCTCCTAATATTAACATTCCTAGCATACCACTGTCCCCTTCT 0.5226 LOC286423-[GRIA3]-LOC392533
3870185 rs2473184 X NC_000023.5 121446469 C T AAGCCATCTAGTCAGCTGAGGATGACTAAACAATTCAAAAGACTAAAAAAT 0.274 LOC402422-[THOC2]-BIRC4
3870505 rs6608182 X NC_000023.5 122094859 C T ATACTCTACAGCACATCTCATTCCCCTTATGAACCTGCCTCTAGTCAGTCA 0.3758 LOC392535-[ ]-LOC139116
3875859 rs5931090 X NC_000023.5 134962628 C G TGTATTT1ATCAGACTGTAAATAGGCCTGTTTAGAAGATTTGCTGCATTTT 0.2881 GPR101-[ ]-RAC4
3875872 rs4829606 X NC_000023.5 134977294 A T GTAAGAGAAAGACTTAAGAACCTGTAACAATATTGAATCCACAATCAGATA 0.2731 GPR101-[ ]-RAC4
3876840 rs12556549 X NC_000023.5 136846343 G T GTCCAATTTTCTATATCAGTTGTTAGAATTGACCATTAACTCTATAATATT 0.8783 FGF13-[ ]-SRD5AP1
3876937 rs6528600 X NC_000023.5 137002181 A G TATAACCATTTCTGTGGGTTCAGCAATCACCAACCAGAGAGAGGTAAATTG 0.9805 FGF13-[ ]-SRD5AP1
3881931 rs5952057 X NC_000023.5 145491215 C G CACTGTAAGGCCTTCTGTGTTAAAACAGCAGCCTTGCCTCCAGCACACATA 0.0838 LOC158813-[ ]-FMR1
3881989 rs5905149 X NC_000023.5 145575900 C A GGTCTTGTCTAGGGAGGAATGCACCCAATCCAAACAAATCATGACATGCCA 0.8331 LOC158813-[ ]-FMR1
3896084 rs4828524 X NC_000023.5 16462614 A G CTGGAATGCAGCTGAAATGACAGAAATGTTCCGAGCACTTTTTTTTTTTTT 0.1917 RNU4P6-[REPS2] PRO0386
3896625 rs6418752 X NC_000023.5 21397671 G A GTGGGCTGCTGTCTCCTGATGCTGCGTGGTGTGCCCCATGGACATTTGAAA 0.3301 SMS [ ] PHEX
3901134 rs6631192 X NC_000023.5 30223585 G A TCACAAAAAAGCTGGTITTCATCAAGTCATGCACTGATTTGCATCTATTCT 0.3481 GK-[TAB3]-FTHL17
3901755 rs5927030 X NC_000023.5 31066019 G A TATGCTAATGATCTCTATTCCAGGCGAACAAATGTCCTCTGAATTTCCTTT 0.6497 FTHL17-[DMD]-LOC389843
3904418 rs5928767 X NC_000023.5 34614015 T A GACATACAGCAAAACACTTCTAAGCTTTTTTTTTAATAGCAAGTTTAAGTT 0.8431 LOC392440-[ ]-LOC340571
3904449 rs5928811 X NC_000023.5 34696754 C T CTTTTATTTTTTAAGTGAAGTGAAACGGTAACCTGTGCTAACAGGAAGCAA 0.8347 LOC392440-[ ]-LOC340571
3993569 rs7569023 2 NC_000002.6 10346596 A G TGGGGCAGGCCCAGAATGGCCCTGAATCCAGTAACACCAACTGTCCCTGGA 0.819 RRM2-[FLJ25102]-HPCAL1
4008972 rs777317 2 NC_000002.6 215938741 C G TATGGTATTTGGGGGACTAGAATTACAAATAGGCTCTGTGGTGCTTTTTTC 0.0212 LOC285176 [ ]-ABCA12
4027550 rs4552392 3 NC_000003.6 187030386 C T AGAATCTGGGTTCAAGTCCAGGTGGCATGGCTTCCAGGCTGGCATGTGATG 0.739 SFRS10, LOC344887 [ ]-ETV5
4032210 rs2651148 3 NC_000003.6 194882597 A G TGATAGGAAATGGGGCTTCAGGTTGAAATCAGATGAGAGCTGGCCTCTGAG 0.1719 OPA1-[ ]-LOC389186
4040872 rs6835973 4 NC_000004.6 187375123 A G TGCTGTTCAGAGCATTGCTGACACCAGGGCATGAAACTAGTGACACAGTTA 0.7602 PRO0618-[ARGBP2]-TLR3
4044139 rs4402996 4 NC_000004.6 163806913 G C CTTTTTTTGATATTATACAAAGAGTGAGATACAAAGGCATTTGTTTTATTA 0.836 DKFZp566D234-[ ]-LOC92345
4080468 rs4617096 7 NC_000007.8 118816377 A C CAGGAAAGTAGTGAATTGTGGCACAAAGCTGGAATATGCTGTCTTTTCCTT 0.8485 ANKRD7-[ ]-KCND2
4092120 rs7826501 8 NC_000008.6 65726252 C A AGTTTTCCTGGGGAAGCCGAGGCCGCCTAGAGGCAGAAAGCTGTCATCCCG 0.793 BHLHB5-[CYP7B1] LOC389665
4122930 rs2904981 11 NC_000011.5 64778386 C T ATCATTTCCTTGACTGCTGTCCTAACGTTGGATGTTTGAATAGGGGTTTTG 0.1365 CAPN1, LOC387780 [ ] POLA2
4122932 rs1633466 11 NC_000011.5 64791533 C G ATATTTTGGTGGCTTGGCTCTGGCTCGGACCCTGGCTGTGTAGGCCTGGTC 0.1263 CAPN1, LOC387780 [ ] POLA2
4139599 rs1358221 12 NC_000012.6 104428922 T C CATTCTTCTCAGGACCTTTGCTCTTTGCCTTTCTCTGTCTGAAGGTTCACT 0.5152 LOC387882-[LOC390355]-LOC245718
4150772 rs6496481 15 NC_000015.5 86693066 C T CCATGCTTACTCACTCTATGACCCACTGAGTAAAAGCTAGTTTGGAATAAA 0.7881 NTRK3-[ ] MRPL46, MRPS11
4171006 rs2302845 18 NC_000018.5 52597765 G A TGTGGTCTTAGGTGAGAGAAGCCGCGCAGGCCCTGCTTCTGGCGGAACTGA 0.363 TXNL-[WDR7]-MGC33608
4213286 rs2735801 14 NC_000014.4 103569724 T A TTATAAAATGATGATTCACTTTGTCTAATATCTCAGTTTTTATAATTAATC 0.78 GPR132-[ ] JAG2, NUDT14
4232561 rs8084365 18 NC_000018.5 12869737 T A AAAATACTAAATTCATTTTTCCCGCTAGAATTTCAACAAGGTATCAAGTTC 0.9583 HCCA3-[PTPN2]-SEC13L
4283222 rs6466702 7 NC_000007.8 118802003 T C CTGGAGGGATCCGAGACCCACTCTCTTATTTTTCCTTCTGAACAAAAGCCT 0.8463 ANKRD7-[ ]-KCND2
4295305 rs7591439 2 NC_000002.6 113189939 G A TCCAGACTTACAAGATTACTTCATGGTGAAAGTTTGGATTGATCAATAATT 0.6101 FLJ41410 [ ] LOC400998,
LOC389020
4320535 rs2651158 3 NC_000003.6 194905895 C T CAGTTCCAGCAGGGTTGGGTGAGACCTCAGGGTGATGCATGGGCACTGTTT 0.7213 OPA1-[ ]-LOC389186
4336765 rs5912040 X NC_000023.5 115502230 T C AGAGCTGAAGGAAAGGGTATTTATATATAAGCTGTTCTTGGTCCTAAAAAA 0.8931 LOC392527-[ ]-KLHL13
4353088 rs4629907 8 NC_000008.6 65800787 T C GCTTGTACCTTGCTTACTAACATTGTGCTGCAATCACATGGCCAAGTCCAA 0.7907 LOC389665, CYP7B1 [ ]-LOC392227
4404676 rs4240146 X NC_000023.5 11685568 A C TAACCACCACCTTGGCTACATCTTCACTTTATACTTTCACAGGAGATTTTG 0.8801 MSL3L1-[KIAA0316]-PRPS2
4428163 rs6001009 22 NC_000022.5 36748395 A G GCCCCAGACTTTGGGGGGCCCATCTACAAACCTAGGCTCACCCAGAATCCT 0.6073 PRKCABP, SLC16A8 [FLJ22582]
PLA2G6
4431812 rs6438666 3 NC_000003.6 122836521 T C ATGAATGAAACTGATGTGGCAGTATTTATAAACAGATGTAAATGGGAGATT 0.3773 GOLGB1 [KIAA0036] EAF2
4436593 rs6505114 17 NC_000017.6 27644703 G A CTAAAGGCAAGCAACATAAAGATAAGTAAGCCCAGTGTCAGAGCTCAGGCT 0.4524 PIPOX-[LOC399700] LOC400589
4442429 rs6589848 11 NC_000011.5 120261670 T C CTGTATTCAGTAAAGGAGTATTCGGTGAGGGGGAAGTTCATGATCAAATGT 0.183 ARHGEF12-[GRIK4]-MGC10233
4449341 rs6825537 4 NC_000004.6 189356525 C T TTAAGACCAGTCTTTCTAACTAACCCAGTCAGACAAAAATAAAGAAAAAGT 0.6902 LOC389248-[ ] LOC391726
4453632 rs6997149 8 NC_000008.6 65773767 G A ACAGGAATAGCTGAGGAAAAAGGCTGCTTATCATGATCTTCCTCTGCTGAG 0.7908 LOC389665, CYP7B1 [ ]-LOC392227
4476399 rs8089593 18 NC_000018.5 30053081 A T GTCAAATCCATATGAGTATAAACTCATTGTACCAATATCCACGTGAAGCTA 0.7146 KIAA1713-[NOL4]-DTNA
4478770 rs4331673 3 NC_000003.6 135030432 C A TCCACTTCTCCATCGCACTGTCTGCCTTCACACAACTCATTCTTGGTCCTG 0.8586 FLJ22173-[SLCO2A1]-RYK
4486048 rs7825328 8 NC_000008.6 74521967 A T TCAAATCGAACAGGTAGTATTTGTAAGTGACTCCACCTCTTCTTTTACACA 0.1819 RDH10-[STAU2]-FLJ11011
4491310 rs4131154 13 NC_000013.6 106937076 A T GGTAAGAGATACTGGTTATTATGATATAACAAGTGGTGGGATTCTTATGCT 0.7505 TNFSF13B-[ ] MYR8
4516175 rs4129182 7 NC_000007.8 118758986 A T CAGGCAGGGCTAATGTGCAGCTCCCACTTGGATGGGAAGAACAGTGTGTGG 0.1735 ANKRD7-[ ]-KCND2
4545337 rs4973591 2 NC_000002.6 234048294 G A TGGAGCCCTGCCATCTCTCGCTATCGTCTTCTGCCTCTCAACTAGGGGAAT 0.6842 L00389084-[NGEF]-NEU2
4551370 rs6554742 5 NC_000005.5 12714442 G A TAGAGACTAGAGGAGGAGGTAATTGGTTTACATAGGGTCCAGGGGATTGGT 0.8423 CTNND2-[ ]-LOC401175
4552714 rs4489033 5 NC_000005.5 104895319 A T AAGACATAATTGTATAATTTATTCCAATTGCTTTTTTTTAAACAAAAATCT 0.0955 RAB9P1-[ ]-LOC345571
4560172 rs4302812 8 NC_000008.6 103452803 G A GCTGCTGGTCACTGACTCTGAACTGGGAGCCTGATCTTCTTCTCCAGCTCT 0.3865 DD5-[ ]-ODF1
4566219 rs4421782 12 NC_000012.6 128685945 G T ACAGCGATTCTGTAAAGATTTCCAGGGCATATGGTCCCTAAAGGATCATCC 0.7317 N0D25-[KIAA1944]-LOC400088
4571614 rs1539853 18 NC_000018.5 33383431 A G CTGGCAATATTTTTCCAGCTGCAAGACCAGTGTCACCCCAGGAAACTGTCC 0.2537 KIAA1328-[BRUNOL4]-LOC388474
4588473 rs7721152 5 NC_000005.5 117790836 G A TAGTAGGGGAATTTTCTGTTGTCTTGTGTGGTTAACTTCTAGACTGTATTT 0.83 RPS17P2-[ ]-FLJ33977
4589662 rs4534816 15 NC_000015.5 86995087 G A TAATCATTGGGTCTACAGAAACCACGTGCTTGAGAAATGGAAGCCCTGGAG 0.8279 ISG20-[ ]-AGC1
4592239 rs6953246 7 NC_000007.8 666S0912 G A TGTCCACATAAGACAACCTCTGTTCGGAGCAATTAAAGGCGAATCTGGACC 0.4296 FLJ13195-[ ]-AUTS2
4662308 rs4676753 3 NC_000003.6 122849512 T C TATTGGCCATGTAACTTTAGTGGAATGTTGGATAAAGGTCACTAATCTTAT 0.3775 GOLGB1-[KIAA0036] EAF2
4670519 rs5904984 X NC_000023.5 144935838 T C CTTTCCATGTTCCTGACTCCTAAGCTGAACACATTTTAATTTATTATATAT 0.7116 LOC158613-[ ]-FMR1
4672031 rs1594887 18 NC_000018.5 43144356 G A GTTTAATTTCCATGTATCTTGTACCGTTTCCAGAGTTCCTCTCATTATTGT 0.2817 HSPC039-[ ]-LOC400650
10940 rs2823731 21 NC_000021.4 16566315 A G ATACATTATATTTAAACATATCTCTATAGAGTCAACAAAATAAAATAAACA 0.5986 VDAC2P-[LOC388815]-LOC391270
12394 rs2823937 21 NC_000021.4 16947265 A C ATGTAAGATCGTTTGGGAAAATGTTAAGACAGATATCTTGCTTTAATTTTT 0.6183 LOC388815 [ ]-LOC391270
17207 rs2824839 21 NC_000021.4 18746350 C A GCTTATGTTTATGTGATGGCACCTGCGAGTACATAGAGGTTGGATATGTTA 0.5494 PRSS7 [ ]-LOC388816
17255 rs2824848 21 NC_000021.4 18775552 T C ACTCCAACCCACAGCATTATTATTATTCAGTAGGTTATAGAGGTGTTATAC 0.5109 PRSS7-[ ]-LOC388816
20802 rs2825756 21 NC_000021.4 19999393 A G ACCCCTTAAATTTTCATTTTCTCTCAAAGTCTCCTCTAAATTTAGTATATT 0.8111 SLC6A6P-[ ]-C1QBPP
39641 rs928261 21 NC_000021.4 25378214 T C TGATTAGCCTTCCATTTCATAAACCTTTTTTTCCCCTGGAATTGATAATGG 0.3077 LOC400860-[ ]-LOC284821
40257 rs2829674 21 NC_000021.4 25557670 C T ATAAAGTTGGAATTTGGAGTCATGGCCTGAAAAATGTGAGCAAGTAAAGAA 0.5755 LOC400860-[ ]-LOC284821
54303 rs2832046 21 NC_000021.4 29038677 T C TGGAAGGGTAGAACCTTAAGTAGTTTTTCATTCTCTGACTACTCAACTAGA 0.8541 C21orf100-[ ]-C21orf127
75560 rs2226829 21 NC_000021.4 36987160 T G GATTTTGAGGCCATGTTTCCGTTAATCTGGACCGAGAGCCCTCTGGGAGAG 0.311 LOC388823-[ ] SIM2
76470 rs2835628 21 NC_000021.4 37439923 A G AATGCGATTTGATGATTGTAACAGGACAAAATTTTGATTCTTTCGAAATTC 0.2715 DSCR5-[TTC3]-DSCR9
82434 rs2836671 21 NC_000021.4 39052714 G A AGCTAGGTGGTGTTCTCGTGTACATGTTAGAGATGAGGAAACCCAATCTCT 0.6101 ERG-[LOC400866] ETS2
104324 rs1296754 22 NC_000022.5 16360114 G A TCCTTGTTTCCCCCAGCCTTTTGTCGCTTAACATGTTTCTTTATGCTTATT 0.3001 CLCP1-[CECR2]-SLC25A18
120178 rs465736 22 NC_000022.5 28159320 A G GTTCTAGAAGTGACAAAGCTGGGACACAATACCTTTATGCATGAAAAGGTT 0.8434 AP1B1-[REPL1] NEFH
120634 rs740041 22 NC_000022.5 8524653 A G CATCTCTCTTATCATGCTGCCTCCCAACATGCAGGGGAGAGTCCTGGCCTT 0.601 HSPC051, LOC55954
[ASC1p100]-MTMR3
120658 rs2074707 22 NC_000022.5 28534910 G A CTGAATAAATGGCTCAATGAATAACGCACAAGTGAACATGTCAAACTGAAA 0.6 HSPC051 [ASC1p100]-MTMR3
120666 rs17711377 22 NC_000022.5 28537540 C T TTTGGGCAGGTCTGTCCTTGGTTTCCTTATCGATGACCATGCAGCCCTTGC 0.5875 HSPC051 [ASC1p100]-MTMR3
120843 rs2285667 22 NC_000022.5 28708658 T A AGCAAGAAAAGATTACTGTTCTGGCTCCCTTCAGCTTCTATGTCATTGCAT 0.6244 ASC1p100-[MTMR3] LOC400924
120880 rs41157 22 NC_000022.5 28729705 T C CTTGGCCTTGGCTTTCATTTTGCATTGCTCTTAAATAATAAGTTTGCTTCT 0.3814 ASC1p100-[MTMR3] LOC391326,
LOC400924
120906 rs41168 22 NC_000022.5 28742715 A C CTCAGCCCCTGCTCTGAGTGCCATCAATTTAACTGTTTTGTGGTTCTTCTC 0.3829 ASC1p100-[MTMR3]LOC391326,
LOC400924
121018 rs1548389 22 NC_000022.5 28898106 T C AAAGGTATTGGACTTATATCCTTGATAGAATTGTAGACTGAGTCACTATAA 0.5895 MGC26710 [ ]-LIF
133091 rs34770535 22 NC_000022.5 36928983 T A TCCATCCGCTTCCCAGGCAGACCTATCAGCCAGACAGCTTCCGTCTTGCCT 0.9712 C22orf5 [ ] CSNK1E, LOC400927
137315 rs926350 22 NC_000022.5 41702889 C T TAGAGGCAGCCATCAAATCACCACCCGGGAATGTTCAACTGCAAGTGTGCC 0.7844 PACSIN2-[TTLL1] BIK
137829 rs5996341 22 NC_000022.5 42090418 C T GGAGATTTCCTTGACTTCGTCTTCCCTCTTTTGGTCAAATTAAAAAATATC 0.5363 SCUBE1-[C22orf1]-FLJ23588
138564 rs16991431 22 NC_000022.5 42742499 C T ACCCAGGAGGGCTTCTTGGAGGAGGCGGCCAGTAAGATGAGGTTGAAGATA 0.7787 CGI-51-[PARVB]-TRSPP1
145360 rs6007770 22 NC_000022.5 46571750 A G CACCCCACACTGGACACATCCTTATAGGCACTGAGACACTTCTGGGAGCAC 0.8837 LOC400932-[ ]-LOC388914
159809 rs4127784 14 NC_000014.4 26997334 C T CATCTTACAGAGTGAAGTGCCTGATCCTAAGATATGGTGGTCAAAGAGGAT 0.5709 RPL26P3 [ ]-BTF3P2
159815 rs12882372 14 NC_000014.4 27002793 G A GTGCCTGGCCTACGATTTTAATTACGGTAGATTTATATTACACTTAAACCT 0.6128 RPL26P3-[ ]-BTF3P2
160343 rs17114346 14 NC_000014.4 27343901 G C GTATTTTCTTTTAACTTTCAAAACTGTTTTTGCTCCAAAGAACAAAAGCAA 0.9947 LOC387978-[ ]-PRKCM
TABLE 2
Binary Linear Time
Placebo (by SSRI response (by Placebo (by SSRI response (by Placebo (by SSRI response (by
Gene GeneID Function Genotype) Interaction) Genotype) Interaction) Genotype) Interaction)
ADCY2 108 adenylate cyclase 2 (expressed in brain) ANX
ALDH8A1 64577 aldehyde dehydrogenase 8 family, member A1 ANX
ALDH9A1 223 aldehyde dehydrogenase 9 family, member A1. The ANX, INSOM
enzyme catalyzes the dehydrogenation of gamma-
aminobutyraldehyde to gamma-aminobutyric acid (GABA).
AUTS2 26053 autism susceptibility candidate 2 INSOM CLILLY, HAMDT
CDH12 1010 cadherin 12, type 2 (N-cadherin 2). This particular cadherin HAMDT, INSOM
appears to be expressed specifically in the brain and its
temporal pattern of expression would be consistent with a
role during a critical period of neuronal development,
perhaps specifically during synaptogenesis.
CDH18 1016 cadherin 18, type 2. This particular cadherin is expressed INSOM HAMDT
specifically in the central nervous system and is putatively
involved in synaptic adhesion, exon outgrowth and guidance.
DAT1 55885 neuronal specific transcription factor DAT1. (aka LIM domain only CLILLY HAMDT, INSOM
3 (rhombotin-like 2))
DMD 1756 dystrophin (muscular dystrophy, Duchenne and Becker types) CLILLY
DRD2 1813 dopamine receptor D2. A missense mutation in this gene HAMDT
causes myoclonus dystonia; other mutations have been
associated with schizophrenia
GRID2 2895 glutamate receptor, ionotropic, delta 2. Predominant CLILLY CLILLY
excitatory neurotransmitter receptors in the mammalian
brain. GRID2 is a predicted 1,007 amino acid protein that
shares 97% identity with the mouse homolog, which is
expressed selectively in cerebellar Purkinje cells.
GRM8 2918 glutamate receptor, metabotropic 8. The major excitatory CLILLY
neurotransmitter in the central nervous system and
activates both ionotropic and metabotropic glutamate
receptors. Glutamatergic neurotransmission is involved in
most aspects of normal brain function and can be perturbed
in many neuropathologic conditions.
HTR2C 3358 5-hydroxytryptamine (serotonin) receptor 2C. Higher CLILLY
distribution of the -759T allele of the 5HT2C receptor in
normal controls compared with in patients with
schizophrenia. Involvement of the -759C/T polymorphism of
the 5-HT2CR in clozapine-induced weight gain in German
patients with schizophrenia. 5HTR2C Cys23Ser
polymorphism may be associated with migraine with aura in
a Japanese population.
HTR3A 3359 5-hydroxytryptamine (serotonin) receptor 3A. This gene ANX, INSOM
encodes subunit A of the type 3 receptor for 5-
hydroxytryptamine (serotonin), a biogenic hormone that
functions as a neurotransmitter. This receptor causes fast,
depolarizing responses in neurons after activation.
LAMA2 3908 laminin, alpha 2 (merosin, congenital muscular dystrophy). CLILLY CLILLY
Mutations in this gene have been identified as the cause of
congenital merosin-deficient muscular dystrophy.
LARS2 23395 leucyl-tRNA synthase 2, mitochondrial. Upregulation of INSOM INSOM
LARS2 is a hallmark of 324A > G mutation. The
accumulation of 324A > G mutation in the brain may havea
pathophysiologic role in bipolar disorder and schizophrenia.
LOC399921 399921 (similar to SHANK2) INSOM
NCAM1 4684 neural cell adhesion molecule 1. Genetic variations in INSOM
neural cell adhesion molecule 1 or nearby genes could
confer risks associated with bipolar affective disorder in
Japanese individuals.
PHYH 5264 phytanoyl-CoA 2-hydroxylase. Genetic variations underlie INSOM
Refsum disease, an autosomal recessive disorder
characterized clinically by a tetrad of abnormalities: retinitis
pigmentosa, peripheral neuropathy, cerebellar ataxia, and
elevated protein levels in the cerebrospinal fluid (CSF)
without an increase in the number of cells in the CSF.
PNR 9038 putative neurotransmitter receptor CLILLY
ROBO1 6091 roundabout, axon guidance receptor, homolog 1. This HAMDT ANX, CLILLY,
receptor is involved in the decision by axons to cross the HAMDT
central nervous system midline.
SEMA5A 9037 sema domain, seven thrombospondin repeats (type 1 and ANX INSOM
type 1-like), transmembrane domain (TM) and short
cytoplasmic domain, (semaphorin) 5A. Involved in axonal
guidance during neural development.
SHANK2 22941 SH3 and multiple ankyrin repeat domains 2. This gene ANX, INSOM
encodes a protein that is a member of the Shank family of
synaptic proteins that may function as molecular scaffolds
in the postsynaptic density (PSD). The alternative splicing
demonstrated in Shank genes has been suggested as a
mechanism for regulating the molecular structure of Shank
and the spectrum of Shank-interacting proteins in the PSDs
of adult and developing brain.
SLC1A1 6505 solute carrier family 1 (neuronal/epithelial high affinity ANX
glutamate transporter)
SLC5A7 60482 solute carrier family 5 (choline transporter), member 7. HAMDT
Neurotransmitter of the central and peripheral nervous
system that regulates a variety of autonomic, cognitive, and
motor functions. SLC5A7 is a Na(+)- and Cl(−)-dependent
high-affinity transporter that mediates the uptake of choline
for acetylcholine synthesis in cholinergic neurons.
SLC6A14 11254 solute carrier family 6 (neurotransmitter transporter), CLILLY
member 14. Transports both neutral and cationic amino
acids in an Na(+)- and Cl(−)-dependent manner.
WFS1 7466 Wolfram syndrome 1 (wolframin). Diverse neurologic INSOM
symptoms, including a predisposition to psychiatric illness,
may also be associated with this disorder. A large number
and variety of mutations in this gene, particularly in exon 8,
can be associated with this syndrome. Mutations in this
gene can also cause autosomal dominant deafness 6
(DFNA6), also known as DFNA14 or DFNA38.
WNT2 7472 wingless-type MMTV integration site family member 2. A CLILLY
strong candidate gene for autism.
TABLE 3
Alleles
SNP SNP reference alternate
PerI ID dbSNP rsID Chrom. Accession Position base base Flanking Sequence Gene Analysis
2783077 rs1460969 5 NC_000005.5 7818388 G A CAAATGATATAACGGCAGAAATACCGTATCTCGTATCTCTATTGACTGTGA ADCY2 BIA
3118987 n/a 5 NC_000005.5 7838724 G A AATTCTCCCAACTTTGTTATTGGTCGTTGAGATGATACACATTCAGTACCA ADCY2 BIA
280097 rs728030 6 NC_000006.6 135226864 C A GATTTGTATACTATTGAGGTATTAACGATCCATATTTAACCAAGTGTTTTC ALDH8A1 LIA
1128559 rs4578194 1 NC_000001.5 162837993 C T TGACATTGAAGACCAGAATGGTTCACTTGATGAGAGTCCCCAAAGCTAGTG ALDH9A1 TIA
555251 rs1003404 7 NC_000007.8 68467077 T C TGTCTTTATCTGCACTATAAAATACTGCAGCCTAGCTGGATGAGACGGTTA AUTS2 LGC, LGH
555297 rs10487947 7 NC_000007.8 68416498 G A GTGCCCAGCCCCTGGTGATTTTATGGAGAACTTACTCTGTGCCCTTGGATA AUTS2 Genotype
555302 n/a 7 NC_000007.8 68407681 G A TACAAGTATGATAGCATCAAACACAGGGCTTAGTTTGCATGCCCTCTTATA AUTS2 Genotype
1572691 rs17762851 7 NC_000007.8 69630695 C T CAAGTAATTGAATCTTCTAATGGAACAAACTGGTCTCTGCTTAATGATTTG AUTS2 BGI
4592239 rs6953246 7 NC_000007.8 66650912 G A TGTCCACATAAGACAACCTCTGTTCGGAGCAATTAAAGGCGAATCTGGACC AUTS2 Genotype
3686735 rs4492078 5 NC_000005.5 21838097 A T ATTTCCCATTTGTACACATGCAATATGATTAAAATAGATCTCTAAAGAAGA CDH12 LGI
3686757 rs13153198 5 NC_000005.5 21860993 T C GCTTCACTTTTCTGCCTTTACTTTGCTATTGGAAATTCCTATAATTTGCCT CDH12 LGI, LGH
3686764 rs6452004 5 NC_000005.5 21869848 G T TTTTCATCATCTCCTTTCCTGGGGTGTTTTCACCTCACCATTGGAGGCAGC CDH12 LGI
3687650 rs7726038 5 NC_000005.5 23251375 T G TTTGCGAAGATGTTTCCTATTGCCTTAAATACTTGCCTTGCACAGTAGCTT CDH12 Linear,
Genotype
3687661 rs10038864 5 NC_000005.5 23272263 A T TTGATGGAATTGGAAAGGCAATTTCAGCTCTAAATCACCACAAATCTTCAG CDH12 Linear,
Genotype
3686058 rs16885644 5 NC_000005.5 19694961 A T GAAGCAAAATATATACAAGTTAAAGATATGTGTTCAGCTTCAGTCCAGTCT CDH18 BII, LIH
906272 rs7304507 12 NC_000012.6 16545580 G A CACAACTGTATCTGAACAGATTCTCGITACATAAAACCGCACACACAGTGT DAT1 LGH, LGI
3901755 rs5927030 X NC_000023.5 31066019 G A TATGCTAATGATCTCTATTCCAGGCGAACAAATGTCCTCTGAATTTCCTTT DMD LIC
612631 rs1107162 11 NC_000011.5 112826688 A G TGGGTGTCTGAGGCCCTTGCCCCTCGCTTATCTTCTCCCAGATACATAAGA DRD2 BIH
1752273 rs10891539 11 NC_000011.5 112774141 G C GTAACCCCGGGAGCTGAGTGAGAGAGGCTCCTTCCCTTACATCCACATGCC DRD2 BIH
1752293 rs754672 11 NC_000011.5 112786785 C T TCCTGGGCCACTGAATTGCCAACTGCGTGACCCAAGGCTCCTCTAAACCTG DRD2 BIH
3434449 rs6824100 4 NC_000004.6 94964127 G T CTTTTTGTAAGAGGATACAATAAAAGTATGAGTCAAAGAATATATTGGGGA GRID2 BIC, LIC
528496 rs2237794 7 NC_000007.8 126346076 G C TCAAATTAAGGGGATCATCAACAACGTTTTCTACAGTTCACATAGGAGGCG GRM8 TGC
3868546 n/a X NC_000023.5 112688913 G A CAGCCTTTATCCTCAGAGCAATAACGATGATAGTGACAGTTCTTGACTTTT HTR2C LIC
1752882 rs17626940 11 NC_000011.5 113430360 G A CACTGAGTAAGCAGGTGCCTCCAAAGGTCTTACTAAGCCACAGGTAGGAAG HTR3A TIA
1529845 rs17056873 6 NC_000006.6 129456505 C G TTGAAAGCTTCTGTAAACAGTTGAACTTCAAATTAAAAGGTAAGTAGGAAC LAMA2 LIC
1529998 rs265326 6 NC_000006.6 129570746 C G GTTTATTTTTCATGGTTTTAACCCAGCATTAAGTAGCATGGTTTTTAGCAT LAMA2 TIC
1530007 rs265392 6 NC_000006.6 129576597 A T AATATGAAAGAGACATGTGAATCTCTGCCTTTGAATACTTAGGATGTGTTT LAMA2 TIC
355828 rs9375582 6 NC_000006.6 128938976 T G TTTGTAACTTCCTTGAAGGCAGAGTTTCTTCTTCGGGTTTGTATTATCTAT LAMA2 Interaction,
CLilly
2358053 rs11130066 3 NC_000003.6 45489589 C T GTGTAATACCCTTAGCTTTATATCTCTCAGTTTTCACACAATGTGTTGTAT LARS2 BII, LII
2358096 rs2578670 3 NC_000003.6 45534058 G T TTAAATTTTTATTTGCATATTTGTTTTCTATCCTAATTCCCTACTGATCTT LARS2 BII, LII
1703484 rs11236931 11 NC_000011.5 70195793 C G CAGCTATTGCTTATGCTCCACGCACCATTTGCCCTTTTGGAGGATCATCGT LOC399921 TII
1752125 rs605843 11 NC_000011.5 112662883 T C GGTGATCAGCATGCTGCTGGCCCTATGATGATAAGTAGTGGGCTCTTCCTT NCAM1 LGI
1752273 rs10891539 11 NC_000011.5 112774141 G C GTAACCCCGGGAGCTGAGTGAGAGAGGCTCCTTCCCTTACATCCACATGCC NCAM1 LGI
2210865 rs1556718 10 NC_000010.5 13330966 C A TAAGCTAATCATACCTCCCACTCTGCATCTGAGCAGGGTATCTGAGACTCC PHYH TII
1532522 rs6924201 6 NC_000006.6 132877599 C T GTTCCATAACCTTTGGGGCCAATTACAGGTCATGGATACACTGTTCCTAAG PNR BIC
2386150 rs9866565 3 NC_000003.6 79916897 A G AGTGGTATATAAAACACAGTTGTTGACCACAATATAACTAAGTTACAGAGC ROBO1 Genotype
2386620 rs3773220 3 NC_000003.6 78622704 C T CTCTGCATTAAAATAATAATCATGGCGAGCAACAGATAAAATAATGTTAAA ROBO1 LGH
2386633 rs6788434 3 NC_000003.6 78654588 G A GTATTATACTTCAGTTTACGTAATCGGGAAAATAAGAGTGGTCTAGAGAAA ROBO1 BGH, LGC,
LGH
2386656 rs17016466 3 NC_000003.6 78675379 A G AAACAGTAACAACAACTGTATTTGCATAAGCACCCCATAATCCACACCCAC ROBO1 BGH, LGC,
LGH
2386667 rs3773240 3 NC_000003.6 78703985 C T CTGCTTTCTATGCTGGGGTGGCAACCTAATCCAAAATTCCTATTGCAGGTT ROBO1 LGA, LGC,
LGH
2386700 n/a 3 NC_000003.6 78735232 G A CCTTCTCTCGAAGTTTCTATATGCAGATCATGACTGAATATTGTTGTTTAA ROBO1 BGH
829556 rs3822787 5 NC_000005.5 9345951 A G TTTCATATCCCACACTGAATACCTTGTGATGGCACTGCCACTACCACTGTT SEMA5A LGA
829565 rs6874451 5 NC_000005.5 9339456 C A CCCTTCAAGAGCTGACTGACCAGGGCTGGACAGTTAACTCACTCCTCCAGT SEMA5A
1703484 rs11236931 11 NC_000011.5 70195793 C G CAGCTATTGCTTATGCTCCACGCACCATTTGCCCTTTTGGAGGATCATCGT SHANK2 TIA
863475 rs6476875 9 NC_000009.6 4519671 T C ATTAGATAATTAAAAGCCTCTGCCATCAGTCAAAATGAAACTTTTTTTGTG SLC1A1 BIA
1293364 rs2630505 2 NC_000002.6 108260966 C T TTTCTTTGCAAACCTGTCTTGCCTATTTTTCCTTAGGTTGAAAGGATTCTG SLC5A7 LIH
3857566 rs5952158 X NC_000023.5 114303633 G T ACTAAACAACTGAAATGTTGCACTGGTGACCAATGGGCTGGCTGTCACCAG SLC6A14 BIC
3395544 rs4380588 4 NC_000004.6 6324430 G A GCCATCTCTCCTCCAGGCTGGAGTCGGTGCTTCCCACAGTTACTTCTCACG WFS1 BII
523650 rs39311 7 NC_000007.8 116508620 T G CCCAGGGACCTTTCAATTTTATGCTTATCTTTCTTTATATATTAATATCAA WNT2 LIC
TABLE 4
CNS Relevant Genes
Model Subscale Perlegen_SNP_ID FisherPval FisherQval
BinGeno Hamd T 2386656 0.000779837 0.828149458
BinGeno Hamd T 2386633 0.000789689 0.828149458
BinGeno Hamd T 2386700 0.001988906 0.928914363
BinGeno INSOM 1572691 0.000422659 0.730598063
BinInteract ANX 3123186 0.00000185 0.172688059
BinInteract ANX 2783077 0.0000939 0.884946863
BinInteract ANX 918719 0.000127152 0.884946863
BinInteract ANX 3118987 0.000141478 0.884946863
BinInteract ANX 863475 0.002422978 0.894646315
BinInteract CLILLY 3857566 0.001116038 0.885573423
BinInteract CLILLY 3434449 0.001582873 0.891698664
BinInteract CLILLY 1532522 0.001134751 0.885573423
BinInteract HamdT 918719 1.66E−08 0.003031537
BinInteract HamdT 1752273 0.0000244 0.60757736
BinInteract HamdT 1752293 0.001136911 0.809078132
BinInteract HamdT 612631 0.001603207 0.825277365
BinInteract INSOM 2358096 0.001386535 0.907862841
BinInteract INSOM 3686058 0.001461721 0.907862841
BinInteract INSOM 2358053 0.00147295 0.907862841
BinInteract INSOM 3395544 0.0001657 0.769877609
LinearGeno ANX 2386667 0.000217924 0.942712636
LinearGeno ANX 829556 0.000455991 0.942712636
LinearGeno CLILLY 2386667 0.0000301 0.904680398
LinearGeno CLILLY 2386633 0.0000993 0.904680398
LinearGeno CLILLY 2386656 0.000102605 0.904680398
LinearGeno CLILLY 555251 0.000287397 0.904680398
LinearGeno HamdT 2386667 0.000018 0.607031989
LinearGeno HamdT 2386633 0.0000782 0.896847022
LinearGeno HamdT 2386656 0.0000811 0.896847022
LinearGeno HamdT 555251 0.000475397 0.896847022
LinearGeno HamdT 906272 0.000661222 0.896847022
LinearGeno HamdT 3686757 0.001523578 0.896847022
LinearGeno HamdT 2386620 0.000595901 0.896847022
LinearGeno INSOM 3686764 0.0000394 0.597735223
LinearGeno INSOM 3686757 0.000292836 0.750338675
LinearGeno INSOM 906272 0.000934093 0.892544184
LinearGeno INSOM 1752125 0.001057331 0.892544184
LinearGeno INSOM 3686735 0.001622323 0.905792619
LinearInteract ANX 918719 0.000156764 0.831437921
LinearInteract ANX 280097 0.000185873 0.831437921
LinearInteract CLILLY 3434449 0.000251456 0.694668025
LinearInteract CLILLY 1529845 0.000366086 0.782412669
LinearInteract CLILLY 523650 0.0006434 0.853208783
LinearInteract CLILLY 3868546 0.001672875 0.853208783
LinearInteract CLILLY 3901755 0.003165907 0.853208783
LinearInteract HamdT 918719 0.00000454 0.465870671
LinearInteract HamdT 3686058 0.000696406 0.828221269
LinearInteract HamdT 1293364 0.000848603 0.83215468
LinearInteract Insom 2358096 0.000278621 0.843864781
LinearInteract Insom 2358053 0.000420189 0.903324249
TimeGeno CLILLY 528496 0.000978517 0.459526693
TimeInteract INSOM 3484509 0.0000476 0.217953355
TimeInteract INSOM 1527003 0.0000854 0.239113003
TimeInteract INSOM 3435351 5.66E−05 0.229827322
TimeInteract INSOM 829565 0.000702387 0.256026918
TimeInteract INSOM 2210865 0.000253873 0.24564659
BinGeno Hamd T 2386656 0.000779837 0.828149458
BinGeno Hamd T 2386633 0.000789689 0.828149458
BinGeno Hamd T 2386700 0.001988906 0.928914363
BinGeno INSOM 1572691 0.000422659 0.730598063
BinInteract ANX 3123186 0.00000185 0.172688059
BinInteract ANX 2783077 0.0000939 0.884946863
BinInteract ANX 918719 0.000127152 0.884946863
BinInteract ANX 3118987 0.000141478 0.884946863
BinInteract ANX 863475 0.002422978 0.894646315
BinInteract CLILLY 3857566 0.001116038 0.885573423
BinInteract CLILLY 3434449 0.001582873 0.891698664
BinInteract CLILLY 1532522 0.001134751 0.885573423
BinInteract HamdT 918719 1.66E−08 0.003031537
TABLE 5A
Novel Linear GenotypeANX
Perlegen_SNP FisherPval FisherQval
3480149 7.60E−07 0.14672334
1203638 4.34E−05 0.909972399
1552540 0.000166206 0.942712636
4589662 0.000265204 0.942712636
2349785 0.000357934 0.942712636
2236226 0.00036501 0.942712636
3565269 0.000500392 0.942712636
1871489 0.000505634 0.942712636
670526 0.00050872 0.942712636
3865731 0.000618448 0.942712636
1711184 0.000682355 0.942712636
1871506 0.000688648 0.942712636
3122355 0.000691856 0.942712636
622215 0.000773498 0.942712636
3565203 0.000901856 0.942712636
1203600 0.000994258 0.942712636
3565214 0.001005416 0.942712636
3693100 0.001042893 0.942712636
1800398 0.001106212 0.942712636
2338982 0.001330951 0.942712636
1363739 0.00155695 0.942712636
1234410 0.001614595 0.942712636
507206 0.002048899 0.942712636
3401101 0.002060611 0.942712636
1581736 0.002626153 0.942712636
4171006 0.002636135 0.942712636
160343 0.002707919 0.942712636
10940 0.003258375 0.942712636
3444374 9.56E−05 0.909972399
3444361 0.000100994 0.909972399
1709425 0.002144821 0.942712636
TABLE 5B
CLILLY
Perlegen_SNP FisherPval FisherQval
3819892 4.91E−06 0.54809676
1614288 7.09E−06 0.54809676
3819894 0.0000085 0.54809676
3174413 0.000117562 0.904680398
1586214 0.000230335 0.904680398
848514 0.000255731 0.904680398
526026 0.000294614 0.904680398
1586226 0.000311848 0.904680398
4080468 0.000344132 0.904680398
3122754 0.000346132 0.904680398
1586261 0.00035993 0.915854528
1586311 0.0003752 0.919303147
4283222 0.000393001 0.919303147
497179 0.00039329 0.919303147
4516175 0.000397545 0.919303147
1586171 0.000404069 0.919303147
3612255 0.000537438 0.931747307
891440 0.000590668 0.931747307
1325111 0.000590691 0.931747307
770139 0.000621158 0.931747307
4040872 0.000654293 0.931747307
2369244 0.000722202 0.931747307
1406391 0.000726591 0.931747307
1553131 0.000743514 0.931747307
1476779 0.000756724 0.931747307
303552 0.000949059 0.931747307
1686926 1.12E−03 0.931747307
770116 0.001175479 0.931747307
1124752 0.001192117 0.931747307
3170195 1.20E−03 0.931747307
1778519 1.22E−03 0.931747307
2368729 1.27E−03 0.931747307
1868867 1.40E−03 0.931747307
2343282 1.42E−03 0.931747307
3485444 1.42E−03 0.931747307
3870505 1.43E−03 0.931747307
1385352 1.48E−03 0.931747307
3509817 1.57E−03 0.931747307
1754883 1.93E−03 0.931747307
2378362 2.36E−03 0.931747307
2386700 2.44E−03 0.931747307
3715741 2.48E−03 0.931747307
770100 2.49E−03 0.931747307
3127128 0.002508585 0.931747307
145360 0.002603226 0.931747307
3111057 0.002733873 0.931747307
1507256 0.003177268 0.931747307
1988046 0.0000266 0.904680398
214385 0.000163538 0.904680398
1988073 0.000215354 0.904680398
2386620 0.000226369 0.904680398
944388 0.000311437 0.904680398
736610 0.000542892 0.931747307
3554315 0.000999035 0.931747307
2034022 0.001075507 0.931747307
3560562 0.001293959 0.931747307
TABLE 5C
HMDT
Perlegen_SNP FisherPval FisherQval
3122754 0.0000872 0.896847022
2392173 0.000231798 0.896847022
552812 0.000248879 0.896847022
3820225 0.00029218 0.896847022
1744345 0.000384995 0.896847022
2056363 0.000397117 0.896847022
3326948 0.000420049 0.896847022
3904449 0.000553595 0.896847022
2469920 0.000576937 0.896847022
2056311 0.000631026 0.896847022
3820201 0.000718243 0.896847022
3904418 0.000981211 0.896847022
2342573 0.001130165 0.896847022
982183 0.001166563 0.896847022
2343282 0.001182526 0.896847022
1800398 0.00138105 0.896847022
811022 0.001558082 0.896847022
2392172 0.001580955 0.896847022
3560562 0.001996024 0.896847022
4122932 0.002016422 0.896847022
3715741 0.002053633 0.896847022
3127128 0.002080509 0.896847022
704088 0.002308886 0.896847022
3819892 0.00000513 0.527880571
3819894 6.50E−06 0.527880571
214385 0.000127198 0.896847022
3352050 0.000215055 0.896847022
3170195 5.19E−04 0.896847022
4670519 1.38E−03 0.896847022
TABLE 5D
INSOM
Perlegen_SNP FisherPval FisherQval
3255514 1.75E−05 0.597735223
1059228 0.000042 0.597735223
2267426 0.0000729 0.597735223
3875859 0.0000753 0.597735223
3875872 0.000111592 0.64432005
302732 0.000175396 0.679570313
617225 0.000221704 0.679570313
2351093 0.000279014 0.738377687
617266 0.000335036 0.753411245
1445906 0.000399251 0.792425957
3142103 0.000614577 0.887129335
1661334 0.000702605 0.892544184
4122932 0.000732945 0.892544184
2437138 0.000767675 0.892544184
3263451 0.000820484 0.892544184
4122930 0.000835698 0.892544184
617297 0.000841362 0.892544184
632286 0.000947842 0.892544184
2492846 0.000953843 0.892544184
1096046 0.001007114 0.892544184
2437121 0.001117106 0.892544184
555297 0.001230793 0.896794961
555302 0.001428932 0.905792619
2345656 0.001549704 0.905792619
1390626 0.001640637 0.905792619
3666917 0.001840013 0.905792619
54303 2.12E−03 0.905792619
1205283 0.002162269 0.905792619
617524 0.002284142 0.905792619
3861184 2.37E−03 0.905792619
4428163 2.78E−03 0.905792619
1166312 3.30E−03 0.905792619
2450638 3.41E−03 0.905792619
555380 1.40E−05 0.597735223
2490021 4.63E−05 0.597735223
272259 2.05E−04 0.679570313
2387552 2.19E−04 0.679570313
343816 2.56E−04 0.689832893
2274606 6.58E−04 0.892544184
TABLE 6A
Novel Binary Genotype
ANX
Perlegen_SNP FisherPval FisherQval
3565214 3.74E−05 0.50542105
1552540 5.78E−05 0.50542105
3565203 5.83E−05 0.50542105
3565239 6.06E−05 0.50542105
3565269 6.82E−05 0.50542105
3565292 8.03E−05 0.50542105
3565281 8.13E−05 0.50542105
2993728 8.35E−05 0.50542105
1085506 8.99E−05 0.51524345
3565071 0.000111338 0.569136379
1800398 0.000131748 0.622957831
3444361 0.000169552 0.681000056
1085178 0.000170831 0.681000056
1760288 0.000204967 0.682043477
2790279 0.000211394 0.682043477
2056363 0.000215427 0.682043477
3510699 0.000218452 0.682043477
3332880 0.000225065 0.683003986
3444374 0.000232693 0.683003986
1760335 0.000235817 0.683003986
1660150 0.000271029 0.702213033
4571614 0.00032878 0.721089018
358756 0.000344218 0.731510011
3870185 0.000384177 0.754459136
2099207 0.000402239 0.754459136
3674864 0.000424343 0.754459136
755186 0.000430845 0.754459136
670526 0.000486446 0.793975608
552812 0.000514299 0.812041175
3122754 0.000564623 0.818752203
3443855 0.00066048 0.821882069
3865731 0.00083574 0.821882069
1334452 0.000845319 0.821882069
3303532 0.000963663 0.821882069
2488188 0.000983659 0.821882069
17207 0.000990907 0.821882069
17255 0.001029423 0.821882069
2684490 0.001088913 0.821882069
552869 0.001225311 0.821882069
3708771 0.001311459 0.825432856
3611749 0.00131821 0.825432856
4320535 0.001362934 0.825432856
3122355 0.001641419 0.859979826
1226296 0.001687938 0.865896663
979327 0.001694382 0.866135458
972242 0.002417108 0.883359242
2634363 0.00296125 0.88406624
904811 6.80E−05 0.50542105
163068 0.000434797 0.754459136
3114067 0.001013389 0.821882069
2324234 0.001798169 0.871763249
TABLE 6B
LILLY
Perlegen_SNP FisherPval FisherQval
1912900 3.18E−06 0.596175312
303552 3.40E−05 0.695989982
727193 8.59E−05 0.734767541
2369244 9.39E−05 0.736100904
2048484 1.74E−04 0.76187412
3326948 1.78E−04 0.76187412
3554315 2.01E−04 0.76187412
979327 2.02E−04 0.76187412
552812 2.27E−04 0.809544088
1678333 0.000233957 0.809544088
348386 0.000373255 0.866621002
4476399 0.000381287 0.866621002
3318048 0.000395318 0.866621002
4336765 0.000521725 0.872932395
358303 0.000531893 0.872932395
2153874 0.000562685 0.872932395
532395 0.000738205 0.872932395
2138144 0.000791168 0.872932395
2340118 0.000804415 0.872932395
2314337 0.000812532 0.872932395
769719 0.000838837 0.875967022
1923923 0.000976584 0.892714143
1811416 0.000983074 0.892714143
1613798 0.00100905 0.892714143
256781 0.001115052 0.893838388
1085506 0.001138308 0.893838388
3111057 0.001186916 0.893838388
2147441 0.001299697 0.893838388
906272 0.001324264 0.893838388
1476779 0.001376456 0.893838388
3141936 0.001405744 0.893838388
784172 0.001456013 0.893838388
3666917 0.001539025 0.893838388
472520 0.001565519 0.893838388
516338 0.001745923 0.899583403
2203902 0.00194163 0.899583403
1811405 0.001974277 0.899583403
2405824 0.002197354 0.899583403
411305 0.002328438 0.899583403
2583974 0.002511038 0.899583403
1811387 0.002520753 0.899583403
690495 0.002576258 0.899583403
1001406 0.003106124 0.899583403
138564 0.003294954 0.899583403
159809 0.000405794 0.866621002
159815 0.000421702 0.869490807
739904 0.000467182 0.872932395
3444361 5.83E−04 0.872932395
1689616 0.000627178 0.872932395
1215253 0.000657292 0.872932395
3444374 0.000695425 0.872932395
12394 0.001941884 0.899583403
1912900 3.18E−06 0.596175312
TABLE 6C
HMDT
Perlegen_SNP FisherPval FisherQval
797205 7.86E−05 0.709314361
3303532 8.32E−05 0.709314361
3904418 1.24E−04 0.795496029
2468866 1.51E−04 0.814566784
1337252 1.58E−04 0.814566784
3819894 2.50E−04 0.814566784
945100 2.67E−04 0.822165733
3122754 2.71E−04 0.822165733
20802 3.80E−04 0.828149458
894518 0.000393786 0.828149458
1756543 0.000469699 0.828149458
409576 0.000480102 0.828149458
1905516 0.000504668 0.828149458
1611770 0.000644481 0.828149458
3901134 0.000661764 0.828149458
1085506 0.000663327 0.828149458
1614322 0.000730175 0.828149458
2342573 0.000745396 0.828149458
3748654 0.000765359 0.828149458
104324 0.000786264 0.828149458
3592834 0.000845061 0.828149458
2603232 0.000952835 0.834137568
773759 0.001057905 0.850070392
2084108 0.001078411 0.861045508
3396741 0.001367631 0.899405123
1085178 0.00139558 0.899405123
3554904 0.0014199 0.899405123
2386150 0.001491836 0.899405123
2641152 0.001734342 0.910370919
1614316 0.001789176 0.910793817
1614294 0.00192105 0.922748439
3193146 0.003011683 0.949612679
739904 0.0000213 0.511169381
1919024 0.0000731 0.709314361
3819892 0.000282295 0.822165733
1614290 0.000365771 0.828149458
1369909 0.000406079 0.828149458
3106665 0.000895662 0.828149458
2172827 0.002347173 0.941963678
TABLE 6D
INSOM
Perlegen_SNP FisherPval FisherQval
2001950 4.07E−05 0.357795756
4232561 7.04E−05 0.461502025
2267426 1.53E−04 0.554223547
3875872 1.56E−04 0.554223547
1953297 1.69E−04 0.582369298
1579845 2.17E−04 0.640392906
2677683 2.34E−04 0.640392906
365290 2.82E−04 0.665911054
3477963 2.94E−04 0.665911054
3531432 0.000390416 0.730598063
1534880 0.000497346 0.743456859
3692953 0.000746627 0.78171834
2345857 0.000838902 0.78171834
2420701 0.000862483 0.78171834
1872350 0.000876414 0.78171834
2001971 0.00100183 0.78171834
2450638 0.001022434 0.78171834
1150093 0.001046691 0.784376782
2522402 0.00107975 0.784376782
269181 0.001315011 0.792261726
2475055 0.001343751 0.792261726
3866218 0.001538641 0.809869609
1534840 0.001753581 0.824147879
3263451 0.001896905 0.824147879
3447858 0.002543217 0.824147879
2399557 0.002597211 0.824147879
3181874 0.0026232 0.824147879
4551370 0.002777384 0.824147879
1059228 0.000017 0.282347423
653852 0.000106972 0.53369726
1386738 0.000113385 0.536680775
3271579 0.000133604 0.540105954
272259 0.000227256 0.640392906
883568 0.000230191 0.640392906
2355020 0.001056604 0.784376782
910353 0.001507947 0.809869609
TABLE 7A
Novel Binary Interaction
ANX
Perlegen_SNP FisherPval FisherQval
3123186 1.85E−06 0.172688059
3673009 0.0000496 0.884946863
2039518 9.15E−05 0.884946863
2147954 0.000106072 0.884946863
766107 0.000159418 0.884946863
2394342 0.000178761 0.884946863
679867 0.000219445 0.884946863
1268020 0.000246353 0.884946863
3460224 0.000246582 0.884946863
3296481 0.000295821 0.884946863
1918812 0.000330117 0.884946863
1054104 0.000330847 0.884946863
814339 0.000367622 0.893358301
2009288 0.000457655 0.894646315
2478983 5.58E−04 0.894646315
1410980 0.000569958 0.894646315
668040 0.000631952 0.894646315
2039526 0.000655166 0.894646315
279774 0.000661047 0.894646315
2118459 0.000672331 0.894646315
2118498 0.000682401 0.894646315
814347 0.000684825 0.894646315
3713131 0.000765601 0.894646315
2606259 0.00084099 0.894646315
3876937 0.000861585 0.894646315
1260720 0.000898008 0.894646315
2118500 0.000909127 0.894646315
1816467 0.000953432 0.894646315
499954 0.001012624 0.894646315
3430918 0.001027032 0.894646315
3200432 0.00103623 0.894646315
1054144 0.001144291 0.894646315
2379489 0.001164992 0.894646315
1555949 0.001174928 0.894646315
1921315 0.001376591 0.894646315
3512057 0.001476664 0.894646315
1268046 0.001495458 0.894646315
3339124 0.00161942 0.894646315
3605475 0.001730173 0.894646315
2321879 0.001776967 0.894646315
4672031 0.001803243 0.894646315
3666695 0.002116898 0.894646315
3863206 0.002390844 0.894646315
280907 0.002392077 0.894646315
3107121 0.002535831 0.894646315
3666604 0.002566629 0.894646315
2316249 0.0000784 0.884946863
1812844 0.0000944 0.884946863
522335 0.000160729 0.884946863
TABLE 7B
CLILLY
Perlegen_SNP FisherPval FisherQval
1585755 4.22E−07 0.077530634
1829453 1.40E−05 0.517313148
1276639 1.74E−05 0.517313148
121018 0.0000443 0.626268241
1456212 0.0000589 0.676045239
3596962 0.000091 0.796361322
2147954 0.0000916 0.796361322
1982441 0.000114012 0.805532947
1162438 0.000213482 0.814796791
3328007 0.000242756 0.814796791
120906 2.71E−04 0.814796791
1276713 3.08E−04 0.814796791
120880 0.000373024 0.814796791
2410695 0.000447794 0.814796791
1899724 0.000470189 0.824954655
3417519 0.000485803 0.827452887
1208424 0.000564644 0.850429771
120634 0.000653797 0.885573423
3993569 0.000662617 0.885573423
2474217 0.000719272 0.885573423
120658 0.000750656 0.885573423
2037647 0.00080789 0.885573423
40257 0.000876468 0.885573423
1899741 0.000890829 0.885573423
120843 0.000925325 0.885573423
2931858 0.001095026 0.885573423
3151597 0.001196332 0.885573423
1654367 0.001295452 0.885573423
120666 0.001355155 0.885573423
1468451 0.001382791 0.885573423
3151603 0.001428266 0.885573423
39641 0.001469412 0.885573423
1899780 0.001497294 0.885573423
1616405 0.001568294 0.891698664
3896084 0.001581456 0.891698664
3174758 0.001637129 0.891698664
542193 0.001726239 0.891698664
2997317 0.001768637 0.891698664
2257769 0.00183541 0.892192954
2312380 0.001871729 0.892192954
507284 0.001941043 0.892192954
3848797 0.002284974 0.892192954
1597461 0.002434229 0.892192954
3449937 1.97E−05 0.517313148
75560 0.000174256 0.814796791
4213286 3.43E−04 0.814796791
552991 0.000422671 0.814796791
1585729 0.000427575 0.814796791
TABLE 7C
HMDT
Perlegen_SNP FisherPval FisherQval
1918812 3.72E−05 0.60757736
1918804 4.89E−05 0.60757736
2009288 5.20E−05 0.60757736
1718389 5.52E−05 0.60757736
1276573 8.44E−05 0.60757736
1974444 0.000113195 0.615572839
3322140 0.000121191 0.615572839
1974401 0.00013132 0.630594089
1974421 0.00017814 0.69686637
3700031 0.000188579 0.69686637
1974303 0.000218152 0.69686637
1974527 0.000242629 0.69686637
1971980 0.000255884 0.69686637
3475688 0.000306172 0.69686637
1974476 0.000307586 0.69686637
594176 0.000309842 0.69686637
1974329 0.000327942 0.69686637
1618767 0.000465081 0.781912236
3673009 0.000507853 0.792004627
3386350 0.000520291 0.792004627
1654367 0.00053906 0.792004627
3417519 0.000604733 0.792004627
313699 0.000653236 0.792004627
3594277 0.000672211 0.792004627
4139599 0.000683342 0.794218849
1718430 0.000752184 0.80418697
1119230 0.000801378 0.804943919
1095559 0.000958354 0.804943919
3288843 0.000965382 0.804943919
2486070 0.000997419 0.804943919
2116144 0.001054683 0.804943919
1804744 0.001072266 0.804943919
2009302 0.001085174 0.804943919
2039518 0.001174992 0.809078132
3325587 0.001235909 0.814899938
2041414 0.001471288 0.825277365
898321 0.001523322 0.825277365
3522226 0.001577137 0.825277365
962652 0.001642249 0.825277365
1208424 0.001949287 0.825277365
3522237 0.002101045 0.834350889
2049385 0.002102726 0.834350889
2147936 0.002488053 0.857485245
821871 0.002655072 0.857485245
313717 0.000150857 0.688189146
1645177 0.000232364 0.69686637
3713131 0.000551873 0.792004627
TABLE 7D
INSOM
Perlegen_SNP FisherPval FisherQval
1506595 0.0000512 0.769877609
2022927 0.0000777 0.769877609
492423 0.000125609 0.769877609
1790542 0.00013433 0.769877609
3684385 0.000176913 0.769877609
2022897 0.000189485 0.779065024
2032297 0.00022658 0.81484458
2022921 0.000277437 0.81484458
882595 0.000291303 0.81484458
2118459 0.000301345 0.81484458
2201976 0.000340408 0.81484458
2118498 0.000378114 0.81484458
4442429 0.000464368 0.81484458
2118500 0.000504471 0.820508228
1004017 0.000549364 0.822644008
3594277 5.53E−04 0.822644008
1801860 0.000666931 0.867795214
3288850 0.000678021 0.870222616
903569 0.000749141 0.874873059
3548055 0.000781836 0.874873059
4436593 0.000820021 0.874873059
3511990 0.000843385 0.874873059
813112 0.000945285 0.874873059
368144 0.000972484 0.874873059
1798659 0.000997355 0.88044959
2244319 0.001088076 0.890815319
1646094 0.001167786 0.890815319
3486976 0.001291877 0.907862841
383165 0.001379008 0.907862841
1626238 0.001420778 0.907862841
383212 0.001456677 0.907862841
383214 0.001527116 0.907862841
3288843 0.001861693 0.929507725
334643 0.002154937 0.929507725
4027550 0.002344654 0.929507725
882560 0.002762401 0.929507725
1999459 0.0000743 0.769877609
446808 0.000123552 0.769877609
4588473 2.60E−04 0.81484458
TABLE 8A
Novel Linear Interaction
ANX
Perlegen_SNP FisherPval FisherQval
1276573 5.54E−06 0.690054875
3123186 7.69E−06 0.690054875
1276558 0.0000109 0.690054875
679867 0.0000297 0.802428017
1966373 0.000104802 0.831437921
1276697 0.000143427 0.831437921
2147954 0.000147486 0.831437921
1009275 0.000162966 0.831437921
542193 0.000230103 0.831437921
2451656 0.000250362 0.831437921
2394342 0.000299991 0.831437921
1705437 0.00030737 0.831437921
1276713 0.00032498 0.831437921
1405831 0.000427174 0.831437921
2451662 0.000443097 0.831437921
1276683 0.000450169 0.831437921
1276648 0.000497576 0.831437921
1293364 0.000499701 0.831437921
3296481 0.000511291 0.831437921
1405790 0.000531537 0.831437921
1276639 0.000556925 0.831437921
1953110 0.000579846 0.831437921
3863206 0.00069296 0.846614455
2020226 0.000900507 0.861520912
1276632 0.000924432 0.861520912
3562810 0.000951699 0.861520912
2222231 0.000956645 0.861520912
4404676 0.001016381 0.861520912
1966361 1.07E−03 0.861520912
1067961 0.00111909 0.861520912
2009288 0.001170816 0.861520912
1327662 0.001195037 0.861520912
340241 0.001215751 0.861520912
1943237 0.001262444 0.861520912
1953067 0.001280055 0.861520912
2317228 0.001319994 0.872365434
607843 0.001440926 0.879626447
2328415 0.001460599 0.879626447
1260720 0.00150703 0.890470959
1737980 0.001590802 0.890843761
3670712 0.001726221 0.910379216
342860 0.001793934 0.914302351
1966340 0.00191288 0.914302351
3614176 0.002350182 0.920669311
3614192 0.002644713 0.920669311
2448996 0.000178558 0.831437921
3848852 0.000511764 0.831437921
3713131 0.000531864 0.831437921
120178 0.000662362 0.846614455
TABLE 8B
CLILLY
Perlegen_SNP FisherPval FisherQval
2946891 5.12E−05 0.638207215
4453632 6.97E−05 0.638207215
1125283 0.0000702 0.638207215
75560 0.0000928 0.638207215
4353088 0.000110719 0.664647994
1431533 0.000122898 0.664647994
1829453 0.000128244 0.664647994
2009288 0.000142893 0.664647994
3673009 0.000146588 0.664647994
2147954 0.000154918 0.664647994
3700031 0.000158351 0.664647994
1637827 0.00017212 0.664647994
4092120 0.000194946 0.664647994
3848797 0.000212959 0.664647994
3567213 0.000214566 0.664647994
3862078 0.000297168 0.754714194
3118276 0.00032455 0.782412669
539841 0.000353884 0.782412669
3386350 0.000510755 0.853208783
1992318 0.000742658 0.853208783
120178 0.000810091 0.853208783
1899724 0.00107746 0.853208783
3328007 0.001168322 0.853208783
3862097 0.001170505 0.853208783
3481741 0.001230609 0.853208783
3896625 0.001298284 0.853208783
3641695 0.001416178 0.853208783
3452760 1.54E−03 0.853208783
1276639 0.001801397 0.853208783
441242 0.001823328 0.853208783
1257281 0.001887601 0.853208783
3857566 0.002132232 0.853208783
2009302 0.002205987 0.853208783
295720 0.002448359 0.853208783
1616405 0.002788514 0.853208783
1718389 0.0000241 0.638207215
1718318 0.0000813 0.638207215
1718464 0.0000906 0.638207215
3668870 0.000188479 0.664647994
1585729 0.00025874 0.694668025
2163321 0.000896254 0.853208783
407964 0.001173731 0.853208783
TABLE 8C
HMDT
Perlegen_SNP FisherPval FisherQval
1276573 1.56E−05 0.587718388
2147954 0.0000683 0.808590884
1431533 0.000083 0.808590884
3673009 0.000138062 0.808590884
492423 0.000246481 0.808590884
2022927 0.00024776 0.808590884
3751183 0.000268238 0.808590884
2039518 0.000279019 0.808590884
3713131 0.000288195 0.808590884
1966373 0.000346958 0.808590884
2009288 0.000381859 0.808590884
3862078 0.000414353 0.808590884
3322140 0.000428216 0.808590884
238656 0.000471915 0.809584162
2394342 0.000484275 0.809584162
342860 0.000529174 0.814916867
1966340 0.000600408 0.815837689
3700031 0.000624746 0.815837689
3288843 0.000738017 0.83215468
3862097 0.000847967 0.83215468
75560 0.000869617 0.83215468
2163321 0.000873453 0.83215468
1228577 0.00088711 0.83215468
280097 0.000993832 0.834108886
4295305 0.001020798 0.834108886
1276713 0.001116771 0.834108886
920234 0.001169028 0.834108886
355828 0.001173625 0.834108886
2022921 1.24E−03 0.834108886
3296481 0.001455371 0.834108886
1327662 0.001626338 0.834108886
1255229 0.001683553 0.834108886
2022897 0.001830583 0.834108886
1674227 0.002575817 0.834108886
1276697 0.002758631 0.834108886
1718389 0.0000284 0.710281555
3594277 0.000132887 0.808590884
120178 0.000216002 0.808590884
1637827 0.000309853 0.808590884
456564 0.000768785 0.83215468
340241 0.001083959 0.834108886
3848852 0.001195067 0.834108886
TABLE 8D
INSOM
Perlegen_SNP FisherPval FisherQval
2022927 3.69E−06 0.352035264
2022921 9.33E−06 0.41157311
2022897 0.0000137 0.435168041
882595 0.0000582 0.813843552
3288850 0.0000698 0.813843552
2402372 0.000102337 0.813843552
4552714 0.000137926 0.822423426
1835296 0.000166361 0.843864781
882560 0.000198517 0.843864781
3152805 0.000328147 0.850132495
1933844 0.00035106 0.850132495
806436 0.00043081 0.903324249
1443883 0.000445147 0.92324168
2201976 0.000459083 0.928580435
4592239 0.000488364 0.928580435
1793653 0.000506956 0.928580435
2362180 0.000514903 0.928580435
3288843 0.000734393 0.928580435
2163423 0.000742812 0.928580435
509722 0.000756721 0.928580435
2425790 0.00079793 0.928580435
3687650 0.000921659 0.928580435
1487452 0.000921934 0.928580435
2118500 0.000987775 0.928580435
389068 0.000988607 0.928580435
2118459 0.000990178 0.928580435
1801860 0.001034554 0.928580435
2118498 0.001069126 0.93771496
2734519 1.09E−03 0.93771496
4150772 0.001193171 0.945922473
3881989 0.001491892 0.945922473
3687661 0.001568211 0.947507343
805214 0.001805088 0.947507343
707407 0.001831411 0.947507343
1443605 0.001846362 0.947507343
162110 0.001938188 0.947507343
2362171 0.001993684 0.947507343
3414039 0.002452871 0.947507343
1178707 0.002703093 0.947507343
2011187 0.000261546 0.843864781
2298521 0.000841374 0.928580435
TABLE 9A
Novel Time Genotype
ANX
Perlegen_SNP FisherPval FisherQval
3707022 4.62E−06 0.235784691
2926674 0.000163201 0.424519262
4560172 0.000248978 0.44842821
2899607 0.000249158 0.44842821
2814609 0.000310263 0.46001297
1778519 0.000721743 0.484505028
428043 0.000778985 0.484505028
470618 0.000783983 0.484505028
3528443 0.000865545 0.485779518
1871685 0.000976687 0.497142424
3609443 0.001219375 0.506356705
195161 0.001291125 0.506356705
1273590 0.001551024 0.506356705
1871599 0.001572185 0.506356705
3526374 0.001972571 0.515833505
1097038 0.002002389 0.517482115
1994975 0.002167276 0.517482115
2393872 0.002184268 0.517482115
1953274 0.0022123 0.517482115
1016164 0.002560161 0.517482115
1871356 0.003353166 0.517482115
2024965 0.0000238 0.393476267
3477251 4.66E−05 0.412075398
1442327 1.24E−04 0.424519262
2393802 1.42E−04 0.424519262
664783 0.00021314 0.424519262
2393869 0.000329567 0.46001297
133091 0.000354042 0.46001297
4449341 0.000413976 0.46001297
1068351 0.000420015 0.46001297
82434 0.000448337 0.46001297
2168345 0.000497556 0.46001297
3290010 0.000506156 0.46001297
2393855 0.000637224 0.476997044
772518 0.000964571 0.497142424
799054 0.000981067 0.497142424
2287160 0.001150663 0.506356705
1387272 0.001168355 0.506356705
921310 0.001171036 0.506356705
TABLE 9B
CLILLY
Perlegen_SNP FisherPval FisherQval
897732 2.45E−04 0.41318456
1751158 0.000371169 0.41318456
2129930 0.000644294 0.437981223
1542474 0.000688814 0.437981223
3842849 0.000706702 0.437981223
3293153 0.000757452 0.439831724
872845 0.000850228 0.457229241
3194833 0.000897274 0.457733935
2402892 0.001141571 0.459526693
2129919 0.001319595 0.459526693
2685247 0.001862107 0.489835882
1508781 0.00194803 0.489835882
2528446 0.001987446 0.490336675
1812391 0.002395617 0.497908003
2083902 0.003224027 0.523486735
3112389 0.0000354 0.376972281
1962816 0.0000614 0.41318456
1064263 0.000114319 0.41318456
1507420 0.00013244 0.41318456
2393730 0.000146501 0.41318456
1975561 0.000171247 0.41318456
872816 1.92E−04 0.41318456
2933057 2.12E−04 0.41318456
2016686 2.70E−04 0.41318456
2041419 0.000312286 0.41318456
289615 0.000358779 0.41318456
1110134 0.00055928 0.430111
1863938 0.000962527 0.459526693
3616400 0.001516401 0.481894275
TABLE 9C
HMDT
Perlegen_SNP FisherPval FisherQval
3563568 2.25E−05 0.249391178
2678537 0.0000827 0.332822531
3134360 0.000213409 0.390773007
1139328 0.000372266 0.390773007
3563516 0.000394451 0.390773007
1962816 0.000471096 0.395307587
583166 0.000565653 0.402688916
1139305 0.000593291 0.406019506
3563492 0.000612684 0.406019506
3524022 0.00063592 0.413665189
652898 0.000752324 0.413665189
4008972 0.000789429 0.413665189
3556069 0.000929596 0.413665189
3134325 0.000953244 0.413665189
3115306 0.001058728 0.413665189
1525920 0.001204693 0.420174108
3152573 0.00123702 0.420174108
4478770 0.001280074 0.423209962
3531816 0.001294216 0.423261022
2946402 0.001356481 0.423261022
3125188 0.001514607 0.423261022
3557017 0.001590062 0.423261022
1062376 2.22E−03 0.436828936
3373581 2.42E−03 0.438404385
2159712 2.39E−05 0.249391178
3563548 0.0000252 0.249391178
3819011 0.0000269 0.249391178
3563481 0.0000292 0.249391178
3563460 0.0000318 0.249872575
3613803 0.0000428 0.292000884
3530702 0.000099 0.361446136
2393730 0.000155764 0.390181686
396080 0.000221694 0.390773007
3563628 0.000307602 0.390773007
697891 0.000333853 0.390773007
2275497 0.00034491 0.390773007
2426484 0.00038266 0.390773007
3134356 0.000393166 0.390773007
2372263 0.000406511 0.394068758
1057517 5.01E−04 0.402681881
2128119 5.23E−04 0.402688916
1609848 5.34E−04 0.402688916
765032 5.67E−04 0.402688916
1542978 8.16E−04 0.413665189
3870054 8.75E−04 0.413665189
583132 1.23E−03 0.420174108
1043573 1.91E−03 0.430398146
625834 1.92E−03 0.430398146
TABLE 9D
INSOM
Perlegen_SNP FisherPval FisherQval
2170305 5.32E−05 0.293434184
1266537 0.000094 0.32358147
1266507 0.0000984 0.326256158
1676930 0.000106647 0.328494305
619434 0.000114647 0.328494305
1266553 0.000177716 0.328494305
1266544 0.000204458 0.328494305
137315 0.000327011 0.337109803
4566219 0.000342467 0.337109803
1266518 0.000347196 0.337109803
1912331 0.000556345 0.351426097
2054953 0.000568621 0.351426097
1266440 0.000679701 0.356828226
502021 0.000858376 0.356828226
918677 0.001103536 0.371891524
2214222 0.001239894 0.371891524
2563109 0.001469077 0.371891524
3222073 0.001611094 0.371891524
3592740 0.001848532 0.371891524
3187067 0.0020983 0.378644893
3876840 0.002335442 0.382583156
350246 0.00242566 0.382583156
3447488 3.02E−05 0.255898146
1067713 3.55E−05 0.255898146
1538591 5.16E−05 0.293434184
2473163 0.000119953 0.328494305
3881931 0.000138905 0.328494305
1749997 0.000142746 0.328494305
1311548 0.000156803 0.328494305
849011 0.000231891 0.334958773
1356550 0.000480317 0.349469535
885372 0.000569351 0.351426097
222093 0.00068797 0.356828226
3567949 0.000809638 0.356828226
1219347 0.001545233 0.371891524
4491310 0.001647392 0.371891524
2473181 0.001684149 0.371891524
283793 0.001764281 0.371891524
3561023 0.002865393 0.390706869
TABLE 10A
Novel Time Interaction
ANX
Perlegen_SNP FisherPval FisherQval
3713131 9.15E−06 0.306866978
1142006 5.46E−05 0.306866978
764102 0.000536158 0.377200974
814713 0.000588304 0.377200974
2328162 0.000621617 0.379589409
1084766 0.000702356 0.38405202
3329421 0.000824696 0.38405202
1813965 0.000961741 0.38405202
3713139 0.001229152 0.389198483
2246661 0.001277413 0.389198483
2473479 0.001331496 0.389198483
627822 0.001372247 0.390932515
1970899 0.001565757 0.397278593
519293 0.001606167 0.397278593
331584 0.001958863 0.402125056
137829 0.002155473 0.405909615
3191406 0.002689128 0.413865805
2311188 3.26E−05 0.306866978
363483 3.98E−05 0.306866978
2370749 6.75E−05 0.306866978
2063822 6.92E−05 0.306866978
3404095 7.81E−05 0.306866978
2478857 0.000110399 0.306866978
2402034 0.00011311 0.306866978
2140871 0.000136662 0.318402541
1276506 0.000147878 0.334250414
2469246 0.000166279 0.349741651
1221183 0.00017339 0.35139515
3263776 0.000183931 0.356186695
803273 0.000193952 0.356186695
800376 0.000219992 0.363391865
1205110 0.000231023 0.363391865
3412405 0.000288464 0.363391865
1614525 0.00036689 0.36985778
3288070 0.000394113 0.36985778
2402124 0.000427615 0.369944554
320863 0.000722421 0.38405202
3419155 0.001147717 0.386608801
4486048 0.001244998 0.389198483
TABLE 10B
CLILLY
Perlegen_SNP FisherPval FisherQval
2021615 4.15E−07 0.03756741
2013955 4.81E−07 0.03756741
2863248 0.000804611 0.41730746
908741 0.000832835 0.417435445
4044139 0.001156522 0.418863405
1447578 0.001313825 0.422175319
406464 0.001716397 0.429118827
1929382 0.002010338 0.434304601
842261 0.002027941 0.434304601
2596560 0.002334375 0.436213574
2446882 0.002455637 0.436213574
3117549 0.0000226 0.314577976
3117608 0.000023 0.314577976
2751104 0.0000286 0.318800029
2415217 0.000133376 0.390483336
2977230 0.000160487 0.390483336
1401365 0.000192711 0.390483336
1102760 0.000255908 0.394940024
3118276 2.79E−04 0.394940024
1059350 2.94E−04 0.394940024
208445 3.41E−04 0.394940024
2745240 3.45E−04 0.394940024
2199587 4.81E−04 0.409390172
3448879 0.000540829 0.409390172
519293 0.000546219 0.409390172
1206778 0.001074808 0.418863405
1066286 0.001445325 0.422175319
TABLE 10C
HMDT
Perlegen_SNP FisherPval FisherQval
2142435 1.02E−06 0.132093615
2223295 2.34E−06 0.132093615
2431351 0.00000257 0.132093615
1586038 0.0000511 0.31980934
1586042 0.000135644 0.31980934
3150971 0.000281239 0.32594106
1839162 0.000480641 0.35099799
414780 0.00056594 0.35099799
561917 0.000736895 0.35099799
674238 0.000795846 0.353567555
1136710 0.001195291 0.37398024
1771665 0.00127509 0.378016308
169827 0.001377927 0.37915258
1136732 0.001775531 0.387152393
1667424 0.001921795 0.391942669
486447 0.000036 0.31980934
1596162 0.0000562 0.31980934
4662308 0.0000625 0.31980934
1208382 0.000125181 0.31980934
437310 0.000175495 0.31980934
2228591 1.98E−04 0.31980934
4431812 2.60E−04 0.325592215
2354274 2.97E−04 0.326814783
2040404 5.12E−04 0.35099799
1329983 1.31E−03 0.37915258
4032210 0.001350039 0.37915258
1224387 0.001798156 0.389879921
TABLE 10D
INSOM
Perlegen_SNP FisherPval FisherQval
3484509 4.76E−05 0.217953355
1527003 0.0000854 0.239113003
2340592 1.37E−06 0.121551406
1246865 6.06E−06 0.177647402
2488104 1.95E−05 0.202246478
2027772 0.0000887 0.240564576
76470 0.000107824 0.24564659
3675147 0.000129775 0.24564659
2030091 0.000204348 0.24564659
4545337 0.000225941 0.24564659
481459 0.000309842 0.24564659
2097268 0.000558842 0.249236468
1148525 0.000697271 0.256026918
1232320 0.000748209 0.256370115
761347 0.000923 0.262408796
761361 0.001003284 0.262481603
1071708 0.001310358 0.274344974
2038957 0.001339653 0.274344974
2254679 0.001384269 0.278146832
603200 0.001429538 0.279575331
1803884 0.002026076 0.292569879
1132867 0.002219513 0.293495601
2027435 0.002306692 0.295707052
2060561 0.002870454 0.308997794
594210 0.002925541 0.309239015
2212327 4.38E−05 0.214668503
1064904 0.000104007 0.24564659
3396622 0.000104718 0.24564659
663947 0.000257256 0.24564659
1071700 0.000338154 0.24564659
1046450 0.000357938 0.24564659
1833522 0.000360144 0.24564659
502183 0.000524599 0.249236468
3115452 0.000545186 0.249236468
178191 0.00093653 0.262408796
3287599 0.000977578 0.262408796
882230 0.001633093 0.281881007
